From 530c2c53bf0332b2a079a09b88bdf0a0bcdc9b51 Mon Sep 17 00:00:00 2001 From: Daniel Ellis Date: Fri, 29 Nov 2024 23:54:30 +0000 Subject: [PATCH] Update to standard-names v87 and area-type-table v11 --- data_descriptors/area_type_table/air.json | 2 +- data_descriptors/area_type_table/all_area_types.json | 2 +- data_descriptors/area_type_table/bare_ground.json | 2 +- data_descriptors/area_type_table/burnt_vegetation.json | 2 +- data_descriptors/area_type_table/c3_plant_functional_types.json | 2 +- data_descriptors/area_type_table/c4_plant_functional_types.json | 2 +- data_descriptors/area_type_table/clear_sky.json | 2 +- data_descriptors/area_type_table/cloud.json | 2 +- data_descriptors/area_type_table/convective_cloud.json | 2 +- data_descriptors/area_type_table/crops.json | 2 +- .../area_type_table/crops_of_c3_plant_functional_types.json | 2 +- .../area_type_table/crops_of_c4_plant_functional_types.json | 2 +- data_descriptors/area_type_table/dust_aerosol.json | 2 +- data_descriptors/area_type_table/fire.json | 2 +- data_descriptors/area_type_table/floating_ice.json | 2 +- data_descriptors/area_type_table/floating_ice_shelf.json | 2 +- data_descriptors/area_type_table/fresh_free_water.json | 2 +- data_descriptors/area_type_table/grounded_ice_sheet.json | 2 +- data_descriptors/area_type_table/herbaceous_vegetation.json | 2 +- data_descriptors/area_type_table/ice_and_snow_on_land.json | 2 +- data_descriptors/area_type_table/ice_free_land.json | 2 +- data_descriptors/area_type_table/ice_free_sea.json | 2 +- data_descriptors/area_type_table/ice_on_land.json | 2 +- data_descriptors/area_type_table/ice_sheet.json | 2 +- data_descriptors/area_type_table/lake_ice_or_sea_ice.json | 2 +- data_descriptors/area_type_table/land.json | 2 +- data_descriptors/area_type_table/land_ice.json | 2 +- data_descriptors/area_type_table/melt_pond_free_sea_ice.json | 2 +- data_descriptors/area_type_table/natural_grasses.json | 2 +- .../natural_grasses_of_c3_plant_functional_types.json | 2 +- .../natural_grasses_of_c4_plant_functional_types.json | 2 +- data_descriptors/area_type_table/pastures.json | 2 +- .../area_type_table/pastures_of_c3_plant_functional_types.json | 2 +- .../area_type_table/pastures_of_c4_plant_functional_types.json | 2 +- data_descriptors/area_type_table/permafrost.json | 2 +- .../area_type_table/primary_and_secondary_land.json | 2 +- data_descriptors/area_type_table/primary_deciduous_trees.json | 2 +- data_descriptors/area_type_table/primary_evergreen_trees.json | 2 +- data_descriptors/area_type_table/rain.json | 2 +- data_descriptors/area_type_table/sea.json | 2 +- data_descriptors/area_type_table/sea_ice.json | 2 +- data_descriptors/area_type_table/sea_ice_melt_pond.json | 2 +- data_descriptors/area_type_table/sea_ice_ridges.json | 2 +- data_descriptors/area_type_table/secondary_deciduous_trees.json | 2 +- data_descriptors/area_type_table/secondary_evergreen_trees.json | 2 +- data_descriptors/area_type_table/shrubs.json | 2 +- data_descriptors/area_type_table/smoke.json | 2 +- data_descriptors/area_type_table/snow.json | 2 +- data_descriptors/area_type_table/snow_free_land.json | 2 +- data_descriptors/area_type_table/stratiform_cloud.json | 2 +- data_descriptors/area_type_table/trees.json | 2 +- data_descriptors/area_type_table/unfrozen_soil.json | 2 +- data_descriptors/area_type_table/urban.json | 2 +- data_descriptors/area_type_table/vegetation.json | 2 +- data_descriptors/area_type_table/volcanic_ash_cloud.json | 2 +- data_descriptors/area_type_table/wetland.json | 2 +- .../acoustic_area_backscattering_strength_in_sea_water.json | 2 +- .../standard_name/acoustic_centre_of_mass_in_sea_water.json | 2 +- .../standard_name/acoustic_equivalent_area_in_sea_water.json | 2 +- .../acoustic_index_of_aggregation_in_sea_water.json | 2 +- .../standard_name/acoustic_inertia_in_sea_water.json | 2 +- .../acoustic_proportion_occupied_in_sea_water.json | 2 +- .../acoustic_signal_roundtrip_travel_time_in_sea_water.json | 2 +- .../standard_name/acoustic_target_strength_in_sea_water.json | 2 +- .../acoustic_volume_backscattering_strength_in_sea_water.json | 2 +- .../standard_name/aerodynamic_particle_diameter.json | 2 +- data_descriptors/standard_name/aerodynamic_resistance.json | 2 +- .../standard_name/aerosol_type_in_atmosphere_layer_in_air.json | 2 +- data_descriptors/standard_name/age_of_sea_ice.json | 2 +- data_descriptors/standard_name/age_of_stratospheric_air.json | 2 +- data_descriptors/standard_name/age_of_surface_snow.json | 2 +- data_descriptors/standard_name/aggregate_quality_flag.json | 2 +- data_descriptors/standard_name/air_density.json | 2 +- .../standard_name/air_equivalent_potential_temperature.json | 2 +- data_descriptors/standard_name/air_equivalent_temperature.json | 2 +- data_descriptors/standard_name/air_potential_temperature.json | 2 +- data_descriptors/standard_name/air_pressure.json | 2 +- data_descriptors/standard_name/air_pressure_anomaly.json | 2 +- data_descriptors/standard_name/air_pressure_at_cloud_base.json | 2 +- data_descriptors/standard_name/air_pressure_at_cloud_top.json | 2 +- .../standard_name/air_pressure_at_convective_cloud_base.json | 2 +- .../standard_name/air_pressure_at_convective_cloud_top.json | 2 +- .../standard_name/air_pressure_at_freezing_level.json | 2 +- .../standard_name/air_pressure_at_mean_sea_level.json | 2 +- .../standard_name/air_pressure_at_top_of_atmosphere_model.json | 2 +- .../air_pseudo_equivalent_potential_temperature.json | 2 +- .../standard_name/air_pseudo_equivalent_temperature.json | 2 +- data_descriptors/standard_name/air_temperature.json | 2 +- data_descriptors/standard_name/air_temperature_anomaly.json | 2 +- .../standard_name/air_temperature_at_cloud_top.json | 2 +- ...re_at_effective_cloud_top_defined_by_infrared_radiation.json | 2 +- data_descriptors/standard_name/air_temperature_lapse_rate.json | 2 +- data_descriptors/standard_name/air_temperature_threshold.json | 2 +- data_descriptors/standard_name/altimeter_range.json | 2 +- .../altimeter_range_correction_due_to_dry_troposphere.json | 2 +- .../altimeter_range_correction_due_to_ionosphere.json | 2 +- .../altimeter_range_correction_due_to_wet_troposphere.json | 2 +- data_descriptors/standard_name/altitude.json | 2 +- ...ol_particles_backwards_scattering_by_ranging_instrument.json | 2 +- ...ol_particles_backwards_scattering_by_ranging_instrument.json | 2 +- .../standard_name/altitude_at_top_of_atmosphere_model.json | 2 +- .../standard_name/altitude_at_top_of_dry_convection.json | 2 +- .../amplitude_of_global_average_sea_level_change.json | 2 +- data_descriptors/standard_name/angle_of_emergence.json | 2 +- data_descriptors/standard_name/angle_of_incidence.json | 2 +- .../standard_name/angle_of_rotation_from_east_to_x.json | 2 +- .../standard_name/angle_of_rotation_from_east_to_y.json | 2 +- ...ngle_of_rotation_from_solar_azimuth_to_platform_azimuth.json | 2 +- .../angstrom_exponent_of_ambient_aerosol_in_air.json | 2 +- ...ards_scattering_in_air_due_to_ambient_aerosol_particles.json | 2 +- data_descriptors/standard_name/apparent_air_temperature.json | 2 +- data_descriptors/standard_name/apparent_oxygen_utilization.json | 2 +- data_descriptors/standard_name/area_fraction.json | 2 +- data_descriptors/standard_name/area_fraction_below_surface.json | 2 +- .../area_fraction_of_day_defined_by_solar_zenith_angle.json | 2 +- .../area_fraction_of_night_defined_by_solar_zenith_angle.json | 2 +- ...area_fraction_of_twilight_defined_by_solar_zenith_angle.json | 2 +- data_descriptors/standard_name/area_type.json | 2 +- .../asymmetry_factor_of_ambient_aerosol_particles.json | 2 +- ...tion_optical_thickness_due_to_ambient_aerosol_particles.json | 2 +- ...n_optical_thickness_due_to_black_carbon_ambient_aerosol.json | 2 +- ...optical_thickness_due_to_dust_ambient_aerosol_particles.json | 2 +- ...ical_thickness_due_to_nitrate_ambient_aerosol_particles.json | 2 +- ...to_particulate_organic_matter_ambient_aerosol_particles.json | 2 +- ...cal_thickness_due_to_sea_salt_ambient_aerosol_particles.json | 2 +- ...ical_thickness_due_to_sulfate_ambient_aerosol_particles.json | 2 +- .../standard_name/atmosphere_boundary_layer_thickness.json | 2 +- .../atmosphere_convective_available_potential_energy.json | 2 +- ...phere_convective_available_potential_energy_wrt_surface.json | 2 +- .../standard_name/atmosphere_convective_inhibition.json | 2 +- .../atmosphere_convective_inhibition_wrt_surface.json | 2 +- .../atmosphere_downdraft_convective_mass_flux.json | 2 +- .../standard_name/atmosphere_dry_energy_content.json | 2 +- .../standard_name/atmosphere_dry_static_energy_content.json | 2 +- .../atmosphere_eastward_stress_due_to_gravity_wave_drag.json | 2 +- data_descriptors/standard_name/atmosphere_energy_content.json | 2 +- data_descriptors/standard_name/atmosphere_enthalpy_content.json | 2 +- data_descriptors/standard_name/atmosphere_heat_diffusivity.json | 2 +- data_descriptors/standard_name/atmosphere_helicity.json | 2 +- .../standard_name/atmosphere_horizontal_streamfunction.json | 2 +- .../standard_name/atmosphere_horizontal_velocity_potential.json | 2 +- .../standard_name/atmosphere_hybrid_height_coordinate.json | 2 +- .../atmosphere_hybrid_sigma_pressure_coordinate.json | 2 +- .../standard_name/atmosphere_kinetic_energy_content.json | 2 +- ...r_thickness_expressed_as_geopotential_height_difference.json | 2 +- .../standard_name/atmosphere_level_of_free_convection.json | 2 +- .../atmosphere_level_of_free_convection_wrt_surface.json | 2 +- .../standard_name/atmosphere_lifting_condensation_level.json | 2 +- .../atmosphere_lifting_condensation_level_wrt_surface.json | 2 +- .../standard_name/atmosphere_ln_pressure_coordinate.json | 2 +- .../standard_name/atmosphere_mass_content_of_acetic_acid.json | 2 +- .../standard_name/atmosphere_mass_content_of_aceto_nitrile.json | 2 +- .../standard_name/atmosphere_mass_content_of_alkanes.json | 2 +- .../standard_name/atmosphere_mass_content_of_alkenes.json | 2 +- .../atmosphere_mass_content_of_alpha_hexachlorocyclohexane.json | 2 +- .../standard_name/atmosphere_mass_content_of_alpha_pinene.json | 2 +- .../standard_name/atmosphere_mass_content_of_ammonia.json | 2 +- ...mosphere_mass_content_of_ammonium_dry_aerosol_particles.json | 2 +- ...mass_content_of_anthropogenic_nmvoc_expressed_as_carbon.json | 2 +- .../atmosphere_mass_content_of_aromatic_compounds.json | 2 +- .../atmosphere_mass_content_of_atomic_bromine.json | 2 +- .../atmosphere_mass_content_of_atomic_chlorine.json | 2 +- .../atmosphere_mass_content_of_atomic_nitrogen.json | 2 +- .../standard_name/atmosphere_mass_content_of_benzene.json | 2 +- .../standard_name/atmosphere_mass_content_of_beta_pinene.json | 2 +- ...here_mass_content_of_biogenic_nmvoc_expressed_as_carbon.json | 2 +- .../atmosphere_mass_content_of_bromine_chloride.json | 2 +- .../atmosphere_mass_content_of_bromine_monoxide.json | 2 +- .../atmosphere_mass_content_of_bromine_nitrate.json | 2 +- .../atmosphere_mass_content_of_brox_expressed_as_bromine.json | 2 +- .../standard_name/atmosphere_mass_content_of_butane.json | 2 +- .../atmosphere_mass_content_of_carbon_dioxide.json | 2 +- .../atmosphere_mass_content_of_carbon_monoxide.json | 2 +- .../atmosphere_mass_content_of_carbon_tetrachloride.json | 2 +- .../standard_name/atmosphere_mass_content_of_cfc11.json | 2 +- .../standard_name/atmosphere_mass_content_of_cfc113.json | 2 +- .../standard_name/atmosphere_mass_content_of_cfc113a.json | 2 +- .../standard_name/atmosphere_mass_content_of_cfc114.json | 2 +- .../standard_name/atmosphere_mass_content_of_cfc115.json | 2 +- .../standard_name/atmosphere_mass_content_of_cfc12.json | 2 +- .../atmosphere_mass_content_of_chlorine_dioxide.json | 2 +- .../atmosphere_mass_content_of_chlorine_monoxide.json | 2 +- .../atmosphere_mass_content_of_chlorine_nitrate.json | 2 +- .../atmosphere_mass_content_of_cloud_condensed_water.json | 2 +- .../standard_name/atmosphere_mass_content_of_cloud_ice.json | 2 +- .../atmosphere_mass_content_of_cloud_liquid_water.json | 2 +- .../atmosphere_mass_content_of_clox_expressed_as_chlorine.json | 2 +- ...sphere_mass_content_of_convective_cloud_condensed_water.json | 2 +- .../atmosphere_mass_content_of_convective_cloud_ice.json | 2 +- ...tmosphere_mass_content_of_convective_cloud_liquid_water.json | 2 +- .../atmosphere_mass_content_of_dichlorine_peroxide.json | 2 +- .../atmosphere_mass_content_of_dimethyl_sulfide.json | 2 +- .../atmosphere_mass_content_of_dinitrogen_pentoxide.json | 2 +- .../atmosphere_mass_content_of_dust_dry_aerosol_particles.json | 2 +- ..._mass_content_of_elemental_carbon_dry_aerosol_particles.json | 2 +- .../standard_name/atmosphere_mass_content_of_ethane.json | 2 +- .../standard_name/atmosphere_mass_content_of_ethanol.json | 2 +- .../standard_name/atmosphere_mass_content_of_ethene.json | 2 +- .../standard_name/atmosphere_mass_content_of_ethyne.json | 2 +- .../standard_name/atmosphere_mass_content_of_formaldehyde.json | 2 +- .../standard_name/atmosphere_mass_content_of_formic_acid.json | 2 +- .../atmosphere_mass_content_of_gaseous_divalent_mercury.json | 2 +- .../atmosphere_mass_content_of_gaseous_elemental_mercury.json | 2 +- .../standard_name/atmosphere_mass_content_of_graupel.json | 2 +- .../atmosphere_mass_content_of_graupel_and_hail.json | 2 +- .../standard_name/atmosphere_mass_content_of_hail.json | 2 +- .../standard_name/atmosphere_mass_content_of_halon1202.json | 2 +- .../standard_name/atmosphere_mass_content_of_halon1211.json | 2 +- .../standard_name/atmosphere_mass_content_of_halon1301.json | 2 +- .../standard_name/atmosphere_mass_content_of_halon2402.json | 2 +- .../standard_name/atmosphere_mass_content_of_hcc140a.json | 2 +- .../standard_name/atmosphere_mass_content_of_hcfc141b.json | 2 +- .../standard_name/atmosphere_mass_content_of_hcfc142b.json | 2 +- .../standard_name/atmosphere_mass_content_of_hcfc22.json | 2 +- .../atmosphere_mass_content_of_hexachlorobiphenyl.json | 2 +- .../atmosphere_mass_content_of_hox_expressed_as_hydrogen.json | 2 +- .../atmosphere_mass_content_of_hydrogen_bromide.json | 2 +- .../atmosphere_mass_content_of_hydrogen_chloride.json | 2 +- .../atmosphere_mass_content_of_hydrogen_cyanide.json | 2 +- .../atmosphere_mass_content_of_hydrogen_peroxide.json | 2 +- .../atmosphere_mass_content_of_hydroperoxyl_radical.json | 2 +- .../atmosphere_mass_content_of_hydroxyl_radical.json | 2 +- .../atmosphere_mass_content_of_hypobromous_acid.json | 2 +- .../atmosphere_mass_content_of_hypochlorous_acid.json | 2 +- .../atmosphere_mass_content_of_inorganic_bromine.json | 2 +- .../atmosphere_mass_content_of_inorganic_chlorine.json | 2 +- .../standard_name/atmosphere_mass_content_of_isoprene.json | 2 +- .../standard_name/atmosphere_mass_content_of_limonene.json | 2 +- .../atmosphere_mass_content_of_liquid_precipitation.json | 2 +- ...tmosphere_mass_content_of_mercury_dry_aerosol_particles.json | 2 +- .../standard_name/atmosphere_mass_content_of_methane.json | 2 +- .../standard_name/atmosphere_mass_content_of_methanol.json | 2 +- .../atmosphere_mass_content_of_methyl_bromide.json | 2 +- .../atmosphere_mass_content_of_methyl_chloride.json | 2 +- .../atmosphere_mass_content_of_methyl_hydroperoxide.json | 2 +- .../atmosphere_mass_content_of_methyl_peroxy_radical.json | 2 +- .../atmosphere_mass_content_of_molecular_hydrogen.json | 2 +- ...tmosphere_mass_content_of_nitrate_dry_aerosol_particles.json | 2 +- .../atmosphere_mass_content_of_nitrate_radical.json | 2 +- .../standard_name/atmosphere_mass_content_of_nitric_acid.json | 2 +- ...ent_of_nitric_acid_trihydrate_ambient_aerosol_particles.json | 2 +- .../atmosphere_mass_content_of_nitrogen_monoxide.json | 2 +- .../standard_name/atmosphere_mass_content_of_nitrous_acid.json | 2 +- .../standard_name/atmosphere_mass_content_of_nitrous_oxide.json | 2 +- .../atmosphere_mass_content_of_nmvoc_expressed_as_carbon.json | 2 +- .../atmosphere_mass_content_of_nox_expressed_as_nitrogen.json | 2 +- .../atmosphere_mass_content_of_noy_expressed_as_nitrogen.json | 2 +- .../atmosphere_mass_content_of_oxygenated_hydrocarbons.json | 2 +- .../standard_name/atmosphere_mass_content_of_ozone.json | 2 +- ...ent_of_particulate_organic_matter_dry_aerosol_particles.json | 2 +- .../atmosphere_mass_content_of_peroxy_radicals.json | 2 +- .../atmosphere_mass_content_of_peroxyacetyl_nitrate.json | 2 +- .../atmosphere_mass_content_of_peroxynitric_acid.json | 2 +- ...rimary_particulate_organic_matter_dry_aerosol_particles.json | 2 +- .../standard_name/atmosphere_mass_content_of_propane.json | 2 +- .../standard_name/atmosphere_mass_content_of_propene.json | 2 +- .../standard_name/atmosphere_mass_content_of_radon.json | 2 +- ...mosphere_mass_content_of_sea_salt_dry_aerosol_particles.json | 2 +- ..._of_sea_salt_dry_aerosol_particles_expressed_as_cations.json | 2 +- ...ondary_particulate_organic_matter_dry_aerosol_particles.json | 2 +- .../standard_name/atmosphere_mass_content_of_snow.json | 2 +- .../standard_name/atmosphere_mass_content_of_sulfate.json | 2 +- ...phere_mass_content_of_sulfate_ambient_aerosol_particles.json | 2 +- ...tmosphere_mass_content_of_sulfate_dry_aerosol_particles.json | 2 +- ...nt_of_sulfate_dry_aerosol_particles_expressed_as_sulfur.json | 2 +- .../atmosphere_mass_content_of_sulfur_dioxide.json | 2 +- .../standard_name/atmosphere_mass_content_of_terpenes.json | 2 +- .../standard_name/atmosphere_mass_content_of_toluene.json | 2 +- .../standard_name/atmosphere_mass_content_of_volcanic_ash.json | 2 +- .../standard_name/atmosphere_mass_content_of_water.json | 2 +- ...here_mass_content_of_water_in_ambient_aerosol_particles.json | 2 +- .../standard_name/atmosphere_mass_content_of_water_vapor.json | 2 +- .../standard_name/atmosphere_mass_content_of_xylene.json | 2 +- .../standard_name/atmosphere_mass_of_air_per_unit_area.json | 2 +- .../standard_name/atmosphere_mass_of_carbon_dioxide.json | 2 +- .../standard_name/atmosphere_mass_per_unit_area.json | 2 +- .../atmosphere_mole_content_of_carbon_monoxide.json | 2 +- .../standard_name/atmosphere_mole_content_of_methane.json | 2 +- .../atmosphere_mole_content_of_nitrogen_dioxide.json | 2 +- .../standard_name/atmosphere_mole_content_of_ozone.json | 2 +- .../standard_name/atmosphere_mole_content_of_water_vapor.json | 2 +- .../standard_name/atmosphere_moles_of_acetic_acid.json | 2 +- .../standard_name/atmosphere_moles_of_aceto_nitrile.json | 2 +- .../atmosphere_moles_of_alpha_hexachlorocyclohexane.json | 2 +- .../standard_name/atmosphere_moles_of_alpha_pinene.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_ammonia.json | 2 +- ...sphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json | 2 +- .../standard_name/atmosphere_moles_of_atomic_bromine.json | 2 +- .../standard_name/atmosphere_moles_of_atomic_chlorine.json | 2 +- .../standard_name/atmosphere_moles_of_atomic_nitrogen.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_benzene.json | 2 +- .../standard_name/atmosphere_moles_of_beta_pinene.json | 2 +- .../atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json | 2 +- .../standard_name/atmosphere_moles_of_bromine_chloride.json | 2 +- .../standard_name/atmosphere_moles_of_bromine_monoxide.json | 2 +- .../standard_name/atmosphere_moles_of_bromine_nitrate.json | 2 +- .../atmosphere_moles_of_brox_expressed_as_bromine.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_butane.json | 2 +- .../standard_name/atmosphere_moles_of_carbon_dioxide.json | 2 +- .../standard_name/atmosphere_moles_of_carbon_monoxide.json | 2 +- .../standard_name/atmosphere_moles_of_carbon_tetrachloride.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_cfc11.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_cfc113.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_cfc113a.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_cfc114.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_cfc115.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_cfc12.json | 2 +- .../standard_name/atmosphere_moles_of_chlorine_dioxide.json | 2 +- .../standard_name/atmosphere_moles_of_chlorine_monoxide.json | 2 +- .../standard_name/atmosphere_moles_of_chlorine_nitrate.json | 2 +- .../atmosphere_moles_of_clox_expressed_as_chlorine.json | 2 +- .../standard_name/atmosphere_moles_of_dichlorine_peroxide.json | 2 +- .../standard_name/atmosphere_moles_of_dimethyl_sulfide.json | 2 +- .../standard_name/atmosphere_moles_of_dinitrogen_pentoxide.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_ethane.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_ethanol.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_ethene.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_ethyne.json | 2 +- .../standard_name/atmosphere_moles_of_formaldehyde.json | 2 +- .../standard_name/atmosphere_moles_of_formic_acid.json | 2 +- .../atmosphere_moles_of_gaseous_divalent_mercury.json | 2 +- .../atmosphere_moles_of_gaseous_elemental_mercury.json | 2 +- .../standard_name/atmosphere_moles_of_halon1202.json | 2 +- .../standard_name/atmosphere_moles_of_halon1211.json | 2 +- .../standard_name/atmosphere_moles_of_halon1301.json | 2 +- .../standard_name/atmosphere_moles_of_halon2402.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_hcc140a.json | 2 +- .../standard_name/atmosphere_moles_of_hcfc141b.json | 2 +- .../standard_name/atmosphere_moles_of_hcfc142b.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_hcfc22.json | 2 +- .../standard_name/atmosphere_moles_of_hexachlorobiphenyl.json | 2 +- .../atmosphere_moles_of_hox_expressed_as_hydrogen.json | 2 +- .../standard_name/atmosphere_moles_of_hydrogen_bromide.json | 2 +- .../standard_name/atmosphere_moles_of_hydrogen_chloride.json | 2 +- .../standard_name/atmosphere_moles_of_hydrogen_cyanide.json | 2 +- .../standard_name/atmosphere_moles_of_hydrogen_peroxide.json | 2 +- .../standard_name/atmosphere_moles_of_hydroperoxyl_radical.json | 2 +- .../standard_name/atmosphere_moles_of_hydroxyl_radical.json | 2 +- .../standard_name/atmosphere_moles_of_hypobromous_acid.json | 2 +- .../standard_name/atmosphere_moles_of_hypochlorous_acid.json | 2 +- .../standard_name/atmosphere_moles_of_inorganic_bromine.json | 2 +- .../standard_name/atmosphere_moles_of_inorganic_chlorine.json | 2 +- .../standard_name/atmosphere_moles_of_isoprene.json | 2 +- .../standard_name/atmosphere_moles_of_limonene.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_methane.json | 2 +- .../standard_name/atmosphere_moles_of_methanol.json | 2 +- .../standard_name/atmosphere_moles_of_methyl_bromide.json | 2 +- .../standard_name/atmosphere_moles_of_methyl_chloride.json | 2 +- .../standard_name/atmosphere_moles_of_methyl_hydroperoxide.json | 2 +- .../atmosphere_moles_of_methyl_peroxy_radical.json | 2 +- .../standard_name/atmosphere_moles_of_molecular_hydrogen.json | 2 +- .../standard_name/atmosphere_moles_of_nitrate_radical.json | 2 +- .../standard_name/atmosphere_moles_of_nitric_acid.json | 2 +- ...les_of_nitric_acid_trihydrate_ambient_aerosol_particles.json | 2 +- .../standard_name/atmosphere_moles_of_nitrogen_dioxide.json | 2 +- .../standard_name/atmosphere_moles_of_nitrogen_monoxide.json | 2 +- .../standard_name/atmosphere_moles_of_nitrous_acid.json | 2 +- .../standard_name/atmosphere_moles_of_nitrous_oxide.json | 2 +- .../atmosphere_moles_of_nmvoc_expressed_as_carbon.json | 2 +- .../atmosphere_moles_of_nox_expressed_as_nitrogen.json | 2 +- .../atmosphere_moles_of_noy_expressed_as_nitrogen.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_ozone.json | 2 +- .../standard_name/atmosphere_moles_of_peroxyacetyl_nitrate.json | 2 +- .../standard_name/atmosphere_moles_of_peroxynitric_acid.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_propane.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_propene.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_radon.json | 2 +- .../standard_name/atmosphere_moles_of_sulfur_dioxide.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_toluene.json | 2 +- .../standard_name/atmosphere_moles_of_water_vapor.json | 2 +- data_descriptors/standard_name/atmosphere_moles_of_xylene.json | 2 +- .../standard_name/atmosphere_momentum_diffusivity.json | 2 +- .../atmosphere_net_rate_of_absorption_of_longwave_energy.json | 2 +- .../atmosphere_net_rate_of_absorption_of_shortwave_energy.json | 2 +- .../atmosphere_net_upward_convective_mass_flux.json | 2 +- .../atmosphere_net_upward_deep_convective_mass_flux.json | 2 +- .../atmosphere_net_upward_shallow_convective_mass_flux.json | 2 +- .../atmosphere_northward_stress_due_to_gravity_wave_drag.json | 2 +- .../atmosphere_number_content_of_aerosol_particles.json | 2 +- .../atmosphere_number_content_of_cloud_droplets.json | 2 +- .../atmosphere_number_content_of_ice_crystals.json | 2 +- data_descriptors/standard_name/atmosphere_obukhov_length.json | 2 +- ...here_optical_thickness_due_to_ambient_aerosol_particles.json | 2 +- ...cal_thickness_due_to_ammonium_ambient_aerosol_particles.json | 2 +- ...e_optical_thickness_due_to_black_carbon_ambient_aerosol.json | 2 +- .../atmosphere_optical_thickness_due_to_cloud.json | 2 +- .../atmosphere_optical_thickness_due_to_convective_cloud.json | 2 +- ...optical_thickness_due_to_dust_ambient_aerosol_particles.json | 2 +- ...ere_optical_thickness_due_to_dust_dry_aerosol_particles.json | 2 +- ...ical_thickness_due_to_nitrate_ambient_aerosol_particles.json | 2 +- ...to_particulate_organic_matter_ambient_aerosol_particles.json | 2 +- ...optical_thickness_due_to_pm10_ambient_aerosol_particles.json | 2 +- ..._optical_thickness_due_to_pm1_ambient_aerosol_particles.json | 2 +- ...ptical_thickness_due_to_pm2p5_ambient_aerosol_particles.json | 2 +- ...cal_thickness_due_to_sea_salt_ambient_aerosol_particles.json | 2 +- .../atmosphere_optical_thickness_due_to_stratiform_cloud.json | 2 +- ...ical_thickness_due_to_sulfate_ambient_aerosol_particles.json | 2 +- ...cal_thickness_due_to_water_in_ambient_aerosol_particles.json | 2 +- .../standard_name/atmosphere_potential_energy_content.json | 2 +- data_descriptors/standard_name/atmosphere_sigma_coordinate.json | 2 +- data_descriptors/standard_name/atmosphere_sleve_coordinate.json | 2 +- .../standard_name/atmosphere_stability_k_index.json | 2 +- .../standard_name/atmosphere_stability_showalter_index.json | 2 +- .../standard_name/atmosphere_stability_total_totals_index.json | 2 +- ...ulerian_mean_meridional_overturning_mass_streamfunction.json | 2 +- .../standard_name/atmosphere_updraft_convective_mass_flux.json | 2 +- .../standard_name/atmosphere_upward_absolute_vorticity.json | 2 +- .../standard_name/atmosphere_upward_relative_vorticity.json | 2 +- .../standard_name/atmosphere_x_relative_vorticity.json | 2 +- .../standard_name/atmosphere_y_relative_vorticity.json | 2 +- .../standard_name/attenuated_signal_test_quality_flag.json | 2 +- ...ed_tropical_cyclone_forecasting_system_storm_identifier.json | 2 +- data_descriptors/standard_name/backscattering_ratio_in_air.json | 2 +- .../standard_name/baroclinic_eastward_sea_water_velocity.json | 2 +- .../standard_name/baroclinic_northward_sea_water_velocity.json | 2 +- data_descriptors/standard_name/barometric_altitude.json | 2 +- .../standard_name/barotropic_eastward_sea_water_velocity.json | 2 +- .../standard_name/barotropic_northward_sea_water_velocity.json | 2 +- .../standard_name/barotropic_sea_water_x_velocity.json | 2 +- .../standard_name/barotropic_sea_water_y_velocity.json | 2 +- .../standard_name/basal_downward_heat_flux_in_sea_ice.json | 2 +- data_descriptors/standard_name/baseflow_amount.json | 2 +- ...ltibeam_acoustic_doppler_velocity_profiler_in_sea_water.json | 2 +- data_descriptors/standard_name/beaufort_wind_force.json | 2 +- data_descriptors/standard_name/bedrock_altitude.json | 2 +- .../bedrock_altitude_change_due_to_isostatic_adjustment.json | 2 +- .../standard_name/bedrock_depth_below_ground_level.json | 2 +- data_descriptors/standard_name/biological_taxon_lsid.json | 2 +- data_descriptors/standard_name/biological_taxon_name.json | 2 +- .../standard_name/bioluminescent_photon_rate_in_sea_water.json | 2 +- data_descriptors/standard_name/biomass_burning_carbon_flux.json | 2 +- data_descriptors/standard_name/brightness_temperature.json | 2 +- .../standard_name/brightness_temperature_anomaly.json | 2 +- .../standard_name/brightness_temperature_at_cloud_top.json | 2 +- .../standard_name/brunt_vaisala_frequency_in_air.json | 2 +- data_descriptors/standard_name/burned_area.json | 2 +- data_descriptors/standard_name/burned_area_fraction.json | 2 +- data_descriptors/standard_name/canadian_fire_weather_index.json | 2 +- data_descriptors/standard_name/canopy_albedo.json | 2 +- .../standard_name/canopy_and_surface_water_amount.json | 2 +- data_descriptors/standard_name/canopy_height.json | 2 +- .../canopy_resistance_to_ozone_dry_deposition.json | 2 +- data_descriptors/standard_name/canopy_snow_amount.json | 2 +- data_descriptors/standard_name/canopy_temperature.json | 2 +- data_descriptors/standard_name/canopy_throughfall_flux.json | 2 +- data_descriptors/standard_name/canopy_water_amount.json | 2 +- ...rbon_mass_content_of_forestry_and_agricultural_products.json | 2 +- ...ucts_due_to_anthropogenic_land_use_or_land_cover_change.json | 2 +- ...soil_due_to_anthropogenic_land_use_or_land_cover_change.json | 2 +- .../standard_name/carbon_mass_flux_into_soil_from_litter.json | 2 +- ...on_mass_flux_into_soil_from_vegetation_excluding_litter.json | 2 +- .../standard_name/carbon_mass_transport_in_river_channel.json | 2 +- data_descriptors/standard_name/cell_area.json | 2 +- data_descriptors/standard_name/cell_thickness.json | 2 +- ..._due_to_change_in_sigma_coordinate_wrt_surface_pressure.json | 2 +- ..._due_to_change_in_sigma_coordinate_wrt_surface_pressure.json | 2 +- data_descriptors/standard_name/change_in_land_ice_amount.json | 2 +- data_descriptors/standard_name/change_in_land_ice_mass.json | 2 +- .../change_in_mean_sea_level_wrt_solid_surface.json | 2 +- ...ght_above_reference_ellipsoid_due_to_ocean_tide_loading.json | 2 +- ...nge_in_sea_surface_height_due_to_change_in_air_pressure.json | 2 +- .../change_over_time_in_amount_of_ice_and_snow_on_land.json | 2 +- ...me_in_atmosphere_mass_content_of_water_due_to_advection.json | 2 +- .../standard_name/change_over_time_in_canopy_water_amount.json | 2 +- .../standard_name/change_over_time_in_groundwater_amount.json | 2 +- .../change_over_time_in_land_surface_liquid_water_amount.json | 2 +- .../standard_name/change_over_time_in_land_water_amount.json | 2 +- .../change_over_time_in_mass_content_of_water_in_soil.json | 2 +- .../standard_name/change_over_time_in_river_water_amount.json | 2 +- .../change_over_time_in_sea_water_absolute_salinity.json | 2 +- .../change_over_time_in_sea_water_conservative_temperature.json | 2 +- .../standard_name/change_over_time_in_sea_water_density.json | 2 +- .../change_over_time_in_sea_water_neutral_density.json | 2 +- .../change_over_time_in_sea_water_potential_density.json | 2 +- .../change_over_time_in_sea_water_potential_temperature.json | 2 +- .../change_over_time_in_sea_water_practical_salinity.json | 2 +- .../change_over_time_in_sea_water_preformed_salinity.json | 2 +- .../standard_name/change_over_time_in_sea_water_salinity.json | 2 +- ...ange_over_time_in_sea_water_specific_potential_enthalpy.json | 2 +- .../change_over_time_in_sea_water_temperature.json | 2 +- .../standard_name/change_over_time_in_surface_snow_amount.json | 2 +- ..._time_in_thermal_energy_content_of_ice_and_snow_on_land.json | 2 +- ...hermal_energy_content_of_vegetation_and_litter_and_soil.json | 2 +- ...icient_for_surface_roughness_length_for_momentum_in_air.json | 2 +- data_descriptors/standard_name/clear_sky_area_fraction.json | 2 +- .../standard_name/climatology_test_quality_flag.json | 2 +- data_descriptors/standard_name/cloud_albedo.json | 2 +- data_descriptors/standard_name/cloud_area_fraction.json | 2 +- .../standard_name/cloud_area_fraction_in_atmosphere_layer.json | 2 +- data_descriptors/standard_name/cloud_base_altitude.json | 2 +- data_descriptors/standard_name/cloud_binary_mask.json | 2 +- data_descriptors/standard_name/cloud_ice_mixing_ratio.json | 2 +- .../standard_name/cloud_liquid_water_mixing_ratio.json | 2 +- data_descriptors/standard_name/cloud_top_altitude.json | 2 +- data_descriptors/standard_name/cloud_type.json | 2 +- ...t_number_concentration_of_biological_taxon_in_sea_water.json | 2 +- .../standard_name/compressive_strength_of_sea_ice.json | 2 +- .../compressive_strength_of_unconfined_frozen_soil.json | 2 +- .../standard_name/compressive_strength_of_unconfined_soil.json | 2 +- ...s_equivalent_mass_fraction_of_quinine_sulfate_dihydrate.json | 2 +- data_descriptors/standard_name/convection_time_fraction.json | 2 +- .../standard_name/convective_cloud_area_fraction.json | 2 +- .../convective_cloud_area_fraction_in_atmosphere_layer.json | 2 +- .../standard_name/convective_cloud_base_altitude.json | 2 +- .../standard_name/convective_cloud_base_height.json | 2 +- .../standard_name/convective_cloud_longwave_emissivity.json | 2 +- .../standard_name/convective_cloud_top_altitude.json | 2 +- data_descriptors/standard_name/convective_cloud_top_height.json | 2 +- .../standard_name/convective_precipitation_amount.json | 2 +- .../standard_name/convective_precipitation_flux.json | 2 +- .../standard_name/convective_precipitation_rate.json | 2 +- data_descriptors/standard_name/convective_rainfall_amount.json | 2 +- data_descriptors/standard_name/convective_rainfall_flux.json | 2 +- data_descriptors/standard_name/convective_rainfall_rate.json | 2 +- data_descriptors/standard_name/convective_snowfall_amount.json | 2 +- data_descriptors/standard_name/convective_snowfall_flux.json | 2 +- data_descriptors/standard_name/coriolis_parameter.json | 2 +- .../correction_for_model_negative_specific_humidity.json | 2 +- ...ce_over_longitude_of_northward_wind_and_air_temperature.json | 2 +- .../standard_name/density_ratio_of_dry_soil_to_water.json | 2 +- data_descriptors/standard_name/deployment_latitude.json | 2 +- data_descriptors/standard_name/deployment_longitude.json | 2 +- data_descriptors/standard_name/depth.json | 2 +- .../standard_name/depth_at_base_of_unfrozen_ground.json | 2 +- ...um_upward_derivative_of_sea_water_potential_temperature.json | 2 +- ...epth_at_shallowest_isotherm_defined_by_soil_temperature.json | 2 +- ...oncentration_of_dissolved_molecular_oxygen_in_sea_water.json | 2 +- data_descriptors/standard_name/depth_below_geoid.json | 2 +- data_descriptors/standard_name/depth_below_sea_floor.json | 2 +- .../depth_of_isosurface_of_sea_water_potential_temperature.json | 2 +- data_descriptors/standard_name/dew_point_depression.json | 2 +- data_descriptors/standard_name/dew_point_temperature.json | 2 +- .../standard_name/diameter_of_ambient_aerosol_particles.json | 2 +- ...ce_skin_temperature_and_sea_surface_subskin_temperature.json | 2 +- ...skin_temperature_and_sea_surface_foundation_temperature.json | 2 +- ...surface_subskin_temperature_and_sea_surface_temperature.json | 2 +- ...nce_between_sea_surface_temperature_and_air_temperature.json | 2 +- .../difference_of_air_pressure_from_model_reference.json | 2 +- .../diffuse_downwelling_shortwave_flux_in_air.json | 2 +- ...se_downwelling_shortwave_flux_in_air_assuming_clear_sky.json | 2 +- .../standard_name/dimensionless_exner_function.json | 2 +- .../standard_name/direct_downwelling_shortwave_flux_in_air.json | 2 +- .../direction_of_radial_vector_away_from_instrument.json | 2 +- .../direction_of_radial_vector_toward_instrument.json | 2 +- .../standard_name/direction_of_sea_ice_displacement.json | 2 +- .../standard_name/direction_of_sea_ice_velocity.json | 2 +- data_descriptors/standard_name/distance_from_geocenter.json | 2 +- data_descriptors/standard_name/distance_from_sun.json | 2 +- ..._cyclone_center_to_leading_edge_of_displaced_convection.json | 2 +- .../standard_name/divergence_of_sea_ice_velocity.json | 2 +- data_descriptors/standard_name/divergence_of_wind.json | 2 +- data_descriptors/standard_name/downward_air_velocity.json | 2 +- .../downward_dry_static_energy_flux_due_to_diffusion.json | 2 +- .../standard_name/downward_eastward_momentum_flux_in_air.json | 2 +- ...downward_eastward_momentum_flux_in_air_due_to_diffusion.json | 2 +- .../standard_name/downward_eastward_stress_at_sea_ice_base.json | 2 +- .../downward_heat_flux_at_ground_level_in_snow.json | 2 +- .../downward_heat_flux_at_ground_level_in_soil.json | 2 +- data_descriptors/standard_name/downward_heat_flux_in_air.json | 2 +- .../standard_name/downward_heat_flux_in_floating_ice.json | 2 +- .../standard_name/downward_heat_flux_in_sea_ice.json | 2 +- data_descriptors/standard_name/downward_heat_flux_in_soil.json | 2 +- .../downward_liquid_water_mass_flux_into_groundwater.json | 2 +- .../standard_name/downward_northward_momentum_flux_in_air.json | 2 +- ...ownward_northward_momentum_flux_in_air_due_to_diffusion.json | 2 +- .../downward_northward_stress_at_sea_ice_base.json | 2 +- .../standard_name/downward_sea_ice_basal_salt_flux.json | 2 +- .../downward_water_vapor_flux_in_air_due_to_diffusion.json | 2 +- .../standard_name/downward_x_stress_at_sea_ice_base.json | 2 +- .../standard_name/downward_x_stress_at_sea_water_surface.json | 2 +- .../downward_x_stress_correction_at_sea_water_surface.json | 2 +- .../standard_name/downward_y_stress_at_sea_ice_base.json | 2 +- .../standard_name/downward_y_stress_at_sea_water_surface.json | 2 +- .../downward_y_stress_correction_at_sea_water_surface.json | 2 +- .../standard_name/downwelling_longwave_flux_in_air.json | 2 +- .../downwelling_longwave_flux_in_air_assuming_clear_sky.json | 2 +- ...g_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json | 2 +- ...in_air_assuming_reference_mole_fraction_of_ozone_in_air.json | 2 +- .../standard_name/downwelling_longwave_radiance_in_air.json | 2 +- .../standard_name/downwelling_photon_flux_in_sea_water.json | 2 +- ...ownwelling_photon_flux_per_unit_wavelength_in_sea_water.json | 2 +- .../standard_name/downwelling_photon_radiance_in_sea_water.json | 2 +- ...elling_photon_radiance_per_unit_wavelength_in_sea_water.json | 2 +- .../downwelling_photon_spherical_irradiance_in_sea_water.json | 2 +- ...n_spherical_irradiance_per_unit_wavelength_in_sea_water.json | 2 +- .../downwelling_photosynthetic_photon_flux_in_sea_water.json | 2 +- ...downwelling_photosynthetic_photon_radiance_in_sea_water.json | 2 +- ...photosynthetic_photon_spherical_irradiance_in_sea_water.json | 2 +- .../downwelling_photosynthetic_radiance_in_sea_water.json | 2 +- .../downwelling_photosynthetic_radiative_flux_in_sea_water.json | 2 +- ...elling_photosynthetic_spherical_irradiance_in_sea_water.json | 2 +- .../standard_name/downwelling_radiance_in_sea_water.json | 2 +- .../downwelling_radiance_per_unit_wavelength_in_air.json | 2 +- .../downwelling_radiance_per_unit_wavelength_in_sea_water.json | 2 +- .../standard_name/downwelling_radiative_flux_in_sea_water.json | 2 +- .../downwelling_radiative_flux_per_unit_wavelength_in_air.json | 2 +- ...welling_radiative_flux_per_unit_wavelength_in_sea_water.json | 2 +- .../standard_name/downwelling_shortwave_flux_in_air.json | 2 +- .../downwelling_shortwave_flux_in_air_assuming_clear_sky.json | 2 +- ...shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json | 2 +- ...g_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json | 2 +- ...in_air_assuming_reference_mole_fraction_of_ozone_in_air.json | 2 +- .../standard_name/downwelling_shortwave_flux_in_sea_water.json | 2 +- ...downwelling_shortwave_flux_in_sea_water_at_sea_ice_base.json | 2 +- .../standard_name/downwelling_shortwave_radiance_in_air.json | 2 +- .../downwelling_spherical_irradiance_in_sea_water.json | 2 +- ...g_spherical_irradiance_per_unit_wavelength_in_sea_water.json | 2 +- .../drainage_amount_through_base_of_soil_model.json | 2 +- .../dry_atmosphere_mole_fraction_of_carbon_dioxide.json | 2 +- .../standard_name/dry_atmosphere_mole_fraction_of_methane.json | 2 +- .../standard_name/dry_energy_content_of_atmosphere_layer.json | 2 +- data_descriptors/standard_name/dry_soil_density.json | 2 +- .../dry_static_energy_content_of_atmosphere_layer.json | 2 +- data_descriptors/standard_name/duration_of_sunshine.json | 2 +- .../dvorak_tropical_cyclone_current_intensity_number.json | 2 +- data_descriptors/standard_name/dvorak_tropical_number.json | 2 +- .../standard_name/dynamic_tropopause_potential_temperature.json | 2 +- .../eastward_air_velocity_relative_to_sea_water.json | 2 +- ...sphere_dry_static_energy_transport_across_unit_distance.json | 2 +- ...astward_atmosphere_water_transport_across_unit_distance.json | 2 +- ...d_atmosphere_water_vapor_transport_across_unit_distance.json | 2 +- .../standard_name/eastward_derivative_of_eastward_wind.json | 2 +- .../eastward_derivative_of_northward_sea_ice_velocity.json | 2 +- .../standard_name/eastward_derivative_of_northward_wind.json | 2 +- .../eastward_derivative_of_wind_from_direction.json | 2 +- .../standard_name/eastward_flood_water_velocity.json | 2 +- .../eastward_friction_velocity_at_sea_water_surface.json | 2 +- .../standard_name/eastward_friction_velocity_in_air.json | 2 +- data_descriptors/standard_name/eastward_land_ice_velocity.json | 2 +- data_descriptors/standard_name/eastward_mass_flux_of_air.json | 2 +- .../standard_name/eastward_momentum_flux_correction.json | 2 +- .../standard_name/eastward_sea_ice_displacement.json | 2 +- data_descriptors/standard_name/eastward_sea_ice_velocity.json | 2 +- data_descriptors/standard_name/eastward_sea_water_velocity.json | 2 +- .../eastward_sea_water_velocity_assuming_no_tide.json | 2 +- .../standard_name/eastward_sea_water_velocity_at_sea_floor.json | 2 +- .../eastward_sea_water_velocity_due_to_ekman_drift.json | 2 +- ...ea_water_velocity_due_to_parameterized_mesoscale_eddies.json | 2 +- .../standard_name/eastward_sea_water_velocity_due_to_tides.json | 2 +- .../eastward_transformed_eulerian_mean_air_velocity.json | 2 +- .../standard_name/eastward_water_vapor_flux_in_air.json | 2 +- ...apor_transport_across_unit_distance_in_atmosphere_layer.json | 2 +- data_descriptors/standard_name/eastward_wind.json | 2 +- ..._radius_of_cloud_condensed_water_particles_at_cloud_top.json | 2 +- .../effective_radius_of_cloud_liquid_water_particles.json | 2 +- ..._cloud_liquid_water_particles_at_liquid_water_cloud_top.json | 2 +- .../effective_radius_of_convective_cloud_ice_particles.json | 2 +- ...ctive_radius_of_convective_cloud_liquid_water_particles.json | 2 +- ...id_water_particles_at_convective_liquid_water_cloud_top.json | 2 +- .../effective_radius_of_convective_cloud_rain_particles.json | 2 +- .../effective_radius_of_convective_cloud_snow_particles.json | 2 +- .../effective_radius_of_stratiform_cloud_graupel_particles.json | 2 +- .../effective_radius_of_stratiform_cloud_ice_particles.json | 2 +- ...ctive_radius_of_stratiform_cloud_liquid_water_particles.json | 2 +- ...id_water_particles_at_stratiform_liquid_water_cloud_top.json | 2 +- .../effective_radius_of_stratiform_cloud_rain_particles.json | 2 +- .../effective_radius_of_stratiform_cloud_snow_particles.json | 2 +- ...ectrical_mobility_diameter_of_ambient_aerosol_particles.json | 2 +- ...water_expressed_as_lowercase_delta_13C_relative_to_VPDB.json | 2 +- ..._carbon_dioxide_in_air_expressed_as_uppercase_delta_14C.json | 2 +- ...as_lowercase_delta_15N_relative_to_atmospheric_nitrogen.json | 2 +- .../standard_name/enthalpy_content_of_atmosphere_layer.json | 2 +- data_descriptors/standard_name/equilibrium_line_altitude.json | 2 +- .../equivalent_pressure_of_atmosphere_ozone_content.json | 2 +- .../standard_name/equivalent_reflectivity_factor.json | 2 +- ...equivalent_thickness_at_stp_of_atmosphere_ozone_content.json | 2 +- data_descriptors/standard_name/ertel_potential_vorticity.json | 2 +- .../standard_name/fast_soil_pool_mass_content_of_carbon.json | 2 +- .../standard_name/final_air_pressure_of_lifted_parcel.json | 2 +- data_descriptors/standard_name/fire_area.json | 2 +- data_descriptors/standard_name/fire_radiative_power.json | 2 +- data_descriptors/standard_name/fire_temperature.json | 2 +- data_descriptors/standard_name/flat_line_test_quality_flag.json | 2 +- data_descriptors/standard_name/floating_ice_shelf_area.json | 2 +- .../standard_name/floating_ice_shelf_area_fraction.json | 2 +- data_descriptors/standard_name/floating_ice_thickness.json | 2 +- .../standard_name/flood_water_duration_above_threshold.json | 2 +- data_descriptors/standard_name/flood_water_speed.json | 2 +- data_descriptors/standard_name/flood_water_thickness.json | 2 +- data_descriptors/standard_name/fog_area_fraction.json | 2 +- data_descriptors/standard_name/forecast_period.json | 2 +- data_descriptors/standard_name/forecast_reference_time.json | 2 +- ...ng_photosynthetic_radiative_flux_absorbed_by_vegetation.json | 2 +- ...tion_of_time_with_sea_ice_area_fraction_above_threshold.json | 2 +- .../fractional_saturation_of_oxygen_in_sea_water.json | 2 +- data_descriptors/standard_name/freezing_level_altitude.json | 2 +- .../standard_name/freezing_temperature_of_sea_water.json | 2 +- .../frequency_of_lightning_flashes_per_unit_area.json | 2 +- data_descriptors/standard_name/frozen_soil_density.json | 2 +- .../standard_name/frozen_water_content_of_soil_layer.json | 2 +- .../standard_name/fugacity_of_carbon_dioxide_in_sea_water.json | 2 +- data_descriptors/standard_name/gap_test_quality_flag.json | 2 +- .../standard_name/geoid_height_above_reference_ellipsoid.json | 2 +- data_descriptors/standard_name/geopotential.json | 2 +- data_descriptors/standard_name/geopotential_height.json | 2 +- data_descriptors/standard_name/geopotential_height_anomaly.json | 2 +- .../standard_name/geopotential_height_at_cloud_top.json | 2 +- .../geopotential_height_at_volcanic_ash_cloud_top.json | 2 +- .../standard_name/geostrophic_eastward_sea_water_velocity.json | 2 +- data_descriptors/standard_name/geostrophic_eastward_wind.json | 2 +- .../standard_name/geostrophic_northward_sea_water_velocity.json | 2 +- data_descriptors/standard_name/geostrophic_northward_wind.json | 2 +- .../standard_name/global_average_sea_level_change.json | 2 +- ...al_average_sea_level_change_due_to_change_in_ocean_mass.json | 2 +- .../standard_name/global_average_steric_sea_level_change.json | 2 +- .../global_average_thermosteric_sea_level_change.json | 2 +- .../standard_name/graupel_and_hail_fall_amount.json | 2 +- data_descriptors/standard_name/graupel_and_hail_fall_flux.json | 2 +- data_descriptors/standard_name/graupel_fall_amount.json | 2 +- data_descriptors/standard_name/graupel_fall_flux.json | 2 +- data_descriptors/standard_name/grid_latitude.json | 2 +- data_descriptors/standard_name/grid_longitude.json | 2 +- ...biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json | 2 +- .../gross_primary_productivity_of_biomass_expressed_as_13C.json | 2 +- .../gross_primary_productivity_of_biomass_expressed_as_14C.json | 2 +- ...oss_primary_productivity_of_biomass_expressed_as_carbon.json | 2 +- ...biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice.json | 2 +- ...biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json | 2 +- .../standard_name/gross_range_test_quality_flag.json | 2 +- .../standard_name/gross_rate_of_decrease_in_area_fraction.json | 2 +- .../standard_name/gross_rate_of_increase_in_area_fraction.json | 2 +- data_descriptors/standard_name/ground_level_altitude.json | 2 +- data_descriptors/standard_name/ground_slope_angle.json | 2 +- data_descriptors/standard_name/ground_slope_direction.json | 2 +- data_descriptors/standard_name/grounded_ice_sheet_area.json | 2 +- .../standard_name/grounded_ice_sheet_area_fraction.json | 2 +- ...ion_of_calcareous_phytoplankton_due_to_solar_irradiance.json | 2 +- .../growth_limitation_of_diatoms_due_to_solar_irradiance.json | 2 +- ...n_of_diazotrophic_phytoplankton_due_to_solar_irradiance.json | 2 +- ..._of_miscellaneous_phytoplankton_due_to_solar_irradiance.json | 2 +- ...limitation_of_picophytoplankton_due_to_solar_irradiance.json | 2 +- data_descriptors/standard_name/hail_fall_amount.json | 2 +- data_descriptors/standard_name/hail_fall_flux.json | 2 +- .../standard_name/halosteric_change_in_mean_sea_level.json | 2 +- .../standard_name/halosteric_change_in_sea_surface_height.json | 2 +- data_descriptors/standard_name/harmonic_period.json | 2 +- .../heat_flux_into_sea_water_due_to_flux_adjustment.json | 2 +- .../heat_flux_into_sea_water_due_to_freezing_of_frazil_ice.json | 2 +- .../heat_flux_into_sea_water_due_to_iceberg_thermodynamics.json | 2 +- .../heat_flux_into_sea_water_due_to_newtonian_relaxation.json | 2 +- .../heat_flux_into_sea_water_due_to_sea_ice_thermodynamics.json | 2 +- .../heat_flux_into_sea_water_due_to_snow_thermodynamics.json | 2 +- .../standard_name/heat_index_of_air_temperature.json | 2 +- data_descriptors/standard_name/height.json | 2 +- .../standard_name/height_above_geopotential_datum.json | 2 +- ...ght_above_geopotential_datum_at_top_of_atmosphere_model.json | 2 +- data_descriptors/standard_name/height_above_mean_sea_level.json | 2 +- .../standard_name/height_above_reference_ellipsoid.json | 2 +- data_descriptors/standard_name/height_above_sea_floor.json | 2 +- data_descriptors/standard_name/height_at_cloud_top.json | 2 +- ...ht_at_effective_cloud_top_defined_by_infrared_radiation.json | 2 +- .../standard_name/high_type_cloud_area_fraction.json | 2 +- ...ring_ratio_in_air_over_height_above_reference_ellipsoid.json | 2 +- ...flectivity_factor_over_height_above_reference_ellipsoid.json | 2 +- .../horizontal_atmosphere_dry_energy_transport.json | 2 +- .../horizontal_dry_energy_transport_in_atmosphere_layer.json | 2 +- data_descriptors/standard_name/humidity_mixing_ratio.json | 2 +- data_descriptors/standard_name/ice_cloud_area_fraction.json | 2 +- .../ice_cloud_area_fraction_in_atmosphere_layer.json | 2 +- ...en_ground_expressed_as_fraction_of_frozen_ground_volume.json | 2 +- .../incoming_water_volume_transport_along_river_channel.json | 2 +- ...ltibeam_acoustic_doppler_velocity_profiler_in_sea_water.json | 2 +- data_descriptors/standard_name/institution.json | 2 +- ...oduct_of_conservative_temperature_and_sea_water_density.json | 2 +- ..._product_of_potential_temperature_and_sea_water_density.json | 2 +- ..._wrt_depth_of_product_of_salinity_and_sea_water_density.json | 2 +- .../integral_wrt_depth_of_sea_water_practical_salinity.json | 2 +- .../integral_wrt_depth_of_sea_water_temperature.json | 2 +- ...cy_of_sea_water_alkalinity_expressed_as_mole_equivalent.json | 2 +- ...xpressed_as_mole_equivalent_due_to_biological_processes.json | 2 +- ...tward_wind_and_mass_concentration_of_water_vapor_in_air.json | 2 +- ...eight_of_product_of_eastward_wind_and_specific_humidity.json | 2 +- ...hward_wind_and_mass_concentration_of_water_vapor_in_air.json | 2 +- ...ight_of_product_of_northward_wind_and_specific_humidity.json | 2 +- .../integral_wrt_time_of_air_temperature_deficit.json | 2 +- .../integral_wrt_time_of_air_temperature_excess.json | 2 +- .../integral_wrt_time_of_mole_stomatal_uptake_of_ozone.json | 2 +- ...integral_wrt_time_of_radioactivity_concentration_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_101Mo_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_101Tc_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_102Mo_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_102Tc_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_102mTc_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_103Ru_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_103mRh_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_104Tc_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_105Rh_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_105Ru_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_105mRh_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_106Rh_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_106Ru_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_106mRh_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_107Pd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_107Rh_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_107mPd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_109Pd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_109mAg_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_110mAg_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_111Ag_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_111Pd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_111mAg_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_111mCd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_111mPd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_112Ag_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_112Pd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_113Ag_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_113Cd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_113mAg_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_113mCd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_113mIn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_115Ag_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_115Cd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_115In_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_115mAg_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_115mCd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_115mIn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_116In_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_116mIn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_117Cd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_117In_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_117mCd_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_117mIn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_117mSn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_118Cd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_118In_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_118mIn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_119In_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_119mIn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_119mSn_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_11C_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_121Sn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_121mSn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_123Sn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_123mSn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_124Sb_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_124mSb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_125Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_125Sn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_125mTe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_126Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_126Sn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_126mSb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_127Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_127Sn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_127Te_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_127mTe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_128Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_128Sn_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_128mSb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_129I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_129Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_129Te_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_129mTe_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_129mXe_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_130I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_130Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_130Sn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_130mI_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_130mSb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_131I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_131Sb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_131Te_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_131mTe_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_131mXe_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_132I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_132Te_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_133I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_133Te_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_133Xe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_133mI_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_133mTe_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_133mXe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_134Cs_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_134I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_134Te_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_134mCs_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_134mI_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_134mXe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_135Cs_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_135I_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_135Xe_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_135mBa_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_135mCs_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_135mXe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_136Cs_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_137Cs_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_137Xe_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_137mBa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_138Cs_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_138Xe_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_139Ba_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_13N_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_140Ba_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_140La_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_141Ce_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_141La_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_142Ce_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_142La_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_142Pr_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_142mPr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_143Ce_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_143La_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_143Pr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_144Ce_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_144Nd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_144Pr_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_144mPr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_145Pr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_146Ce_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_146Pr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_147Nd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_147Pm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_147Pr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_147Sm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_148Pm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_148Sm_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_148mPm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_149Nd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_149Pm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_149Sm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_150Pm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_151Nd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_151Pm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_151Sm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_152Nd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_152Pm_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_152mPm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_153Sm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_154Eu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_155Eu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_155Sm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_156Eu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_156Sm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_157Eu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_158Eu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_159Eu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_159Gd_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_15O_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_160Tb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_161Tb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_162Gd_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_162Tb_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_162mTb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_163Tb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_165Dy_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_18F_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_206Hg_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_206Tl_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_207Tl_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_207mPb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_208Tl_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_209Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_209Pb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_209Tl_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_210Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_210Pb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_210Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_210Tl_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_211Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_211Pb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_211Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_212Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_212Pb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_212Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_213Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_213Pb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_213Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_214Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_214Pb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_214Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_215At_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_215Bi_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_215Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_216At_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_216Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_217At_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_217Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_218At_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_218Po_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_218Rn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_219At_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_219Rn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_220Rn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_221Fr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_221Rn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_222Fr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_222Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_222Rn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_223Fr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_223Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_223Rn_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_224Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_225Ac_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_225Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_226Ac_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_226Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_226Th_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_227Ac_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_227Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_227Th_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_228Ac_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_228Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_228Th_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_229Ac_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_229Ra_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_229Th_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_230Pa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_230Th_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_230U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_231Pa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_231Th_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_231U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_232Pa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_232Th_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_232U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_233Pa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_233Th_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_233U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_234Pa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_234Th_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_234U_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_234mPa_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_235Np_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_235Pu_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_235U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_236Np_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_236Pu_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_236U_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_236mNp_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_237Np_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_237Pu_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_237U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_238Np_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_238Pu_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_238U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_239Np_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_239Pu_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_239U_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_240Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_240Np_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_240Pu_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_240U_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_240mNp_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_241Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_241Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_241Pu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_242Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_242Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_242Pu_in_air.json | 2 +- ...t_time_of_radioactivity_concentration_of_242m1Am_in_air.json | 2 +- ...t_time_of_radioactivity_concentration_of_242m2Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_243Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_243Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_243Pu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_244Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_244Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_244Pu_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_244mAm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_245Am_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_245Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_245Pu_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_246Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_247Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_248Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_249Bk_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_249Cf_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_249Cm_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_24Na_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_250Bk_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_250Cf_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_250Cm_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_251Cf_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_252Cf_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_253Cf_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_253Es_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_254Cf_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_254Es_in_air.json | 2 +- ...rt_time_of_radioactivity_concentration_of_254mEs_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_255Es_in_air.json | 2 +- ...al_wrt_time_of_radioactivity_concentration_of_3H_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_41Ar_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_54Mn_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_58Co_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_60Co_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_72Ga_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_72Zn_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_73Ga_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_75Ge_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_77As_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_77Ge_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_77mGe_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_78As_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_78Ge_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_79Se_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_81Se_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_81mSe_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_82Br_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_82mBr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_83Br_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_83Se_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_83mKr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_83mSe_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_84Br_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_84mBr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_85Kr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_85mKr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_86Rb_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_86mRb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_87Kr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_87Rb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_88Kr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_88Rb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_89Kr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_89Rb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_89Sr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_90Sr_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_90Y_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_90mY_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_91Sr_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_91Y_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_91mY_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_92Sr_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_92Y_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_93Y_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_93Zr_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_94Nb_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_94Y_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_94mNb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_95Nb_in_air.json | 2 +- ...l_wrt_time_of_radioactivity_concentration_of_95Y_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_95Zr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_95mNb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_96Nb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_97Nb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_97Zr_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_97mNb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_98Nb_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_99Mo_in_air.json | 2 +- ..._wrt_time_of_radioactivity_concentration_of_99Tc_in_air.json | 2 +- ...wrt_time_of_radioactivity_concentration_of_99mTc_in_air.json | 2 +- .../integral_wrt_time_of_surface_downward_eastward_stress.json | 2 +- .../integral_wrt_time_of_surface_downward_latent_heat_flux.json | 2 +- .../integral_wrt_time_of_surface_downward_northward_stress.json | 2 +- ...ntegral_wrt_time_of_surface_downward_sensible_heat_flux.json | 2 +- ...al_wrt_time_of_surface_downwelling_longwave_flux_in_air.json | 2 +- ...l_wrt_time_of_surface_downwelling_shortwave_flux_in_air.json | 2 +- ...integral_wrt_time_of_surface_net_downward_longwave_flux.json | 2 +- ...ntegral_wrt_time_of_surface_net_downward_shortwave_flux.json | 2 +- .../integral_wrt_time_of_toa_net_downward_shortwave_flux.json | 2 +- .../integral_wrt_time_of_toa_outgoing_longwave_flux.json | 2 +- .../iron_growth_limitation_of_calcareous_phytoplankton.json | 2 +- .../standard_name/iron_growth_limitation_of_diatoms.json | 2 +- .../iron_growth_limitation_of_diazotrophic_phytoplankton.json | 2 +- .../iron_growth_limitation_of_miscellaneous_phytoplankton.json | 2 +- .../iron_growth_limitation_of_picophytoplankton.json | 2 +- data_descriptors/standard_name/isccp_cloud_area_fraction.json | 2 +- ...of_17O_to_16O_in_sea_water_excluding_solutes_and_solids.json | 2 +- ...of_18O_to_16O_in_sea_water_excluding_solutes_and_solids.json | 2 +- .../standard_name/isotropic_longwave_radiance_in_air.json | 2 +- .../isotropic_radiance_per_unit_wavelength_in_air.json | 2 +- .../standard_name/isotropic_shortwave_radiance_in_air.json | 2 +- data_descriptors/standard_name/keetch_byram_drought_index.json | 2 +- .../kinetic_energy_content_of_atmosphere_layer.json | 2 +- ...kinetic_energy_dissipation_in_atmosphere_boundary_layer.json | 2 +- .../standard_name/lagrangian_tendency_of_air_pressure.json | 2 +- .../lagrangian_tendency_of_atmosphere_sigma_coordinate.json | 2 +- data_descriptors/standard_name/land_area_fraction.json | 2 +- data_descriptors/standard_name/land_binary_mask.json | 2 +- data_descriptors/standard_name/land_cover_lccs.json | 2 +- data_descriptors/standard_name/land_ice_area_fraction.json | 2 +- data_descriptors/standard_name/land_ice_basal_drag.json | 2 +- data_descriptors/standard_name/land_ice_basal_melt_rate.json | 2 +- .../land_ice_basal_specific_mass_balance_flux.json | 2 +- data_descriptors/standard_name/land_ice_basal_temperature.json | 2 +- .../standard_name/land_ice_basal_upward_velocity.json | 2 +- data_descriptors/standard_name/land_ice_basal_x_velocity.json | 2 +- data_descriptors/standard_name/land_ice_basal_y_velocity.json | 2 +- data_descriptors/standard_name/land_ice_calving_rate.json | 2 +- .../standard_name/land_ice_lwe_basal_melt_rate.json | 2 +- data_descriptors/standard_name/land_ice_lwe_calving_rate.json | 2 +- .../land_ice_lwe_surface_specific_mass_balance_rate.json | 2 +- data_descriptors/standard_name/land_ice_mass.json | 2 +- .../standard_name/land_ice_mass_not_displacing_sea_water.json | 2 +- data_descriptors/standard_name/land_ice_runoff_flux.json | 2 +- data_descriptors/standard_name/land_ice_sigma_coordinate.json | 2 +- .../land_ice_specific_mass_flux_due_to_calving.json | 2 +- ...specific_mass_flux_due_to_calving_and_ice_front_melting.json | 2 +- data_descriptors/standard_name/land_ice_surface_melt_flux.json | 2 +- .../land_ice_surface_specific_mass_balance_flux.json | 2 +- .../land_ice_surface_specific_mass_balance_rate.json | 2 +- .../standard_name/land_ice_surface_upward_velocity.json | 2 +- data_descriptors/standard_name/land_ice_surface_x_velocity.json | 2 +- data_descriptors/standard_name/land_ice_surface_y_velocity.json | 2 +- data_descriptors/standard_name/land_ice_temperature.json | 2 +- data_descriptors/standard_name/land_ice_thickness.json | 2 +- .../standard_name/land_ice_vertical_mean_x_velocity.json | 2 +- .../standard_name/land_ice_vertical_mean_y_velocity.json | 2 +- data_descriptors/standard_name/land_ice_x_velocity.json | 2 +- data_descriptors/standard_name/land_ice_y_velocity.json | 2 +- .../standard_name/land_surface_liquid_water_amount.json | 2 +- data_descriptors/standard_name/land_water_amount.json | 2 +- data_descriptors/standard_name/latitude.json | 2 +- data_descriptors/standard_name/leaf_area_index.json | 2 +- data_descriptors/standard_name/leaf_mass_content_of_carbon.json | 2 +- .../standard_name/leaf_mass_content_of_nitrogen.json | 2 +- ..._kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json | 2 +- ...ing_averaging_kernel_of_mole_fraction_of_methane_in_air.json | 2 +- data_descriptors/standard_name/lightning_potential_index.json | 2 +- data_descriptors/standard_name/lightning_radiant_energy.json | 2 +- .../standard_name/liquid_water_cloud_area_fraction.json | 2 +- .../liquid_water_cloud_area_fraction_in_atmosphere_layer.json | 2 +- .../standard_name/liquid_water_content_of_permafrost_layer.json | 2 +- .../standard_name/liquid_water_content_of_soil_layer.json | 2 +- .../standard_name/liquid_water_content_of_surface_snow.json | 2 +- ...quid_water_mass_flux_into_soil_due_to_surface_snow_melt.json | 2 +- data_descriptors/standard_name/litter_mass_content_of_13C.json | 2 +- data_descriptors/standard_name/litter_mass_content_of_14C.json | 2 +- .../standard_name/litter_mass_content_of_carbon.json | 2 +- .../standard_name/litter_mass_content_of_nitrogen.json | 2 +- data_descriptors/standard_name/location_test_quality_flag.json | 2 +- ...er_size_distribution_of_aerosol_particles_at_stp_in_air.json | 2 +- ...ed_number_size_distribution_of_aerosol_particles_in_air.json | 2 +- ...distribution_of_cloud_condensation_nuclei_at_stp_in_air.json | 2 +- ...r_size_distribution_of_cloud_condensation_nuclei_in_air.json | 2 +- data_descriptors/standard_name/longitude.json | 2 +- .../standard_name/low_type_cloud_area_fraction.json | 2 +- .../standard_name/lwe_convective_precipitation_rate.json | 2 +- .../standard_name/lwe_convective_snowfall_rate.json | 2 +- data_descriptors/standard_name/lwe_precipitation_rate.json | 2 +- data_descriptors/standard_name/lwe_snowfall_rate.json | 2 +- .../standard_name/lwe_stratiform_precipitation_rate.json | 2 +- .../standard_name/lwe_stratiform_snowfall_rate.json | 2 +- ...lwe_thickness_of_atmosphere_mass_content_of_water_vapor.json | 2 +- .../standard_name/lwe_thickness_of_canopy_water_amount.json | 2 +- .../lwe_thickness_of_convective_precipitation_amount.json | 2 +- .../lwe_thickness_of_convective_snowfall_amount.json | 2 +- .../lwe_thickness_of_frozen_water_content_of_soil_layer.json | 2 +- .../lwe_thickness_of_moisture_content_of_soil_layer.json | 2 +- .../standard_name/lwe_thickness_of_precipitation_amount.json | 2 +- .../standard_name/lwe_thickness_of_snowfall_amount.json | 2 +- .../standard_name/lwe_thickness_of_soil_moisture_content.json | 2 +- .../lwe_thickness_of_stratiform_precipitation_amount.json | 2 +- .../lwe_thickness_of_stratiform_snowfall_amount.json | 2 +- .../standard_name/lwe_thickness_of_surface_snow_amount.json | 2 +- .../lwe_thickness_of_water_evaporation_amount.json | 2 +- data_descriptors/standard_name/lwe_water_evaporation_rate.json | 2 +- .../magnitude_of_air_velocity_relative_to_sea_water.json | 2 +- ...nitude_of_derivative_of_position_wrt_model_level_number.json | 2 +- ...nitude_of_derivative_of_position_wrt_x_coordinate_index.json | 2 +- ...nitude_of_derivative_of_position_wrt_y_coordinate_index.json | 2 +- .../magnitude_of_heat_flux_in_sea_water_due_to_advection.json | 2 +- .../standard_name/magnitude_of_sea_ice_displacement.json | 2 +- .../standard_name/magnitude_of_surface_downward_stress.json | 2 +- ...concentration_of_19_butanoyloxyfucoxanthin_in_sea_water.json | 2 +- ...concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water.json | 2 +- ...equivalent_black_carbon_of_dry_aerosol_particles_in_air.json | 2 +- ...alent_black_carbon_of_pm10_dry_aerosol_particles_in_air.json | 2 +- ...valent_black_carbon_of_pm1_dry_aerosol_particles_in_air.json | 2 +- ...lent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_concentration_of_acetic_acid_in_air.json | 2 +- .../mass_concentration_of_aceto_nitrile_in_air.json | 2 +- ...ss_concentration_of_adenosine_triphosphate_in_sea_water.json | 2 +- .../standard_name/mass_concentration_of_alkanes_in_air.json | 2 +- .../standard_name/mass_concentration_of_alkenes_in_air.json | 2 +- .../mass_concentration_of_alpha_carotene_in_sea_water.json | 2 +- ...ass_concentration_of_alpha_hexachlorocyclohexane_in_air.json | 2 +- .../mass_concentration_of_alpha_pinene_in_air.json | 2 +- .../mass_concentration_of_aluminium_in_sea_floor_sediment.json | 2 +- .../standard_name/mass_concentration_of_ammonia_in_air.json | 2 +- ..._concentration_of_ammonium_dry_aerosol_particles_in_air.json | 2 +- ...ation_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../mass_concentration_of_aromatic_compounds_in_air.json | 2 +- .../mass_concentration_of_arsenic_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_atomic_bromine_in_air.json | 2 +- .../mass_concentration_of_atomic_chlorine_in_air.json | 2 +- .../mass_concentration_of_atomic_nitrogen_in_air.json | 2 +- .../standard_name/mass_concentration_of_benzene_in_air.json | 2 +- .../mass_concentration_of_beta_carotene_in_sea_water.json | 2 +- .../standard_name/mass_concentration_of_beta_pinene_in_air.json | 2 +- ...centration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- ...on_of_biological_taxon_expressed_as_carbon_in_sea_water.json | 2 +- ..._biological_taxon_expressed_as_chlorophyll_in_sea_water.json | 2 +- ..._of_biological_taxon_expressed_as_nitrogen_in_sea_water.json | 2 +- ...tration_of_biomass_burning_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_bromine_chloride_in_air.json | 2 +- .../mass_concentration_of_bromine_monoxide_in_air.json | 2 +- .../mass_concentration_of_bromine_nitrate_in_air.json | 2 +- .../mass_concentration_of_brox_expressed_as_bromine_in_air.json | 2 +- .../standard_name/mass_concentration_of_butane_in_air.json | 2 +- .../mass_concentration_of_cadmium_in_sea_floor_sediment.json | 2 +- ...ous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- .../mass_concentration_of_carbon_dioxide_in_air.json | 2 +- ...concentration_of_carbon_in_dry_aerosol_particles_in_air.json | 2 +- ...ntration_of_carbon_in_pm10_dry_aerosol_particles_in_air.json | 2 +- ...entration_of_carbon_in_pm1_dry_aerosol_particles_in_air.json | 2 +- ...tration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_carbon_monoxide_in_air.json | 2 +- .../mass_concentration_of_carbon_tetrachloride_in_air.json | 2 +- .../mass_concentration_of_carotene_in_sea_water.json | 2 +- .../standard_name/mass_concentration_of_cfc113_in_air.json | 2 +- .../standard_name/mass_concentration_of_cfc113a_in_air.json | 2 +- .../standard_name/mass_concentration_of_cfc114_in_air.json | 2 +- .../standard_name/mass_concentration_of_cfc115_in_air.json | 2 +- .../standard_name/mass_concentration_of_cfc11_in_air.json | 2 +- .../standard_name/mass_concentration_of_cfc12_in_air.json | 2 +- .../mass_concentration_of_chlorine_dioxide_in_air.json | 2 +- .../mass_concentration_of_chlorine_monoxide_in_air.json | 2 +- .../mass_concentration_of_chlorine_nitrate_in_air.json | 2 +- ...ss_concentration_of_chlorophyll_a_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_chlorophyll_a_in_sea_ice.json | 2 +- .../mass_concentration_of_chlorophyll_a_in_sea_water.json | 2 +- .../mass_concentration_of_chlorophyll_b_in_sea_water.json | 2 +- ...ation_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water.json | 2 +- .../mass_concentration_of_chlorophyll_c3_in_sea_water.json | 2 +- .../mass_concentration_of_chlorophyll_c4_in_sea_water.json | 2 +- .../mass_concentration_of_chlorophyll_c_in_sea_water.json | 2 +- .../mass_concentration_of_chlorophyll_in_sea_water.json | 2 +- .../mass_concentration_of_chlorophyllide_a_in_sea_water.json | 2 +- .../mass_concentration_of_chromium_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_cloud_liquid_water_in_air.json | 2 +- ...mass_concentration_of_clox_expressed_as_chlorine_in_air.json | 2 +- ...tration_of_coarse_mode_ambient_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_cobalt_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_condensed_water_in_soil.json | 2 +- .../mass_concentration_of_copper_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_diadinoxanthin_in_sea_water.json | 2 +- ...ncentration_of_diatoms_expressed_as_carbon_in_sea_water.json | 2 +- ...ration_of_diatoms_expressed_as_chlorophyll_in_sea_water.json | 2 +- ...entration_of_diatoms_expressed_as_nitrogen_in_sea_water.json | 2 +- ...otrophic_phytoplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...hic_phytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- .../mass_concentration_of_dichlorine_peroxide_in_air.json | 2 +- .../mass_concentration_of_dimethyl_sulfide_in_air.json | 2 +- .../mass_concentration_of_dinitrogen_pentoxide_in_air.json | 2 +- ...ass_concentration_of_divinyl_chlorophyll_a_in_sea_water.json | 2 +- .../standard_name/mass_concentration_of_drizzle_in_air.json | 2 +- ...mass_concentration_of_dust_dry_aerosol_particles_in_air.json | 2 +- ...ration_of_elemental_carbon_dry_aerosol_particles_in_air.json | 2 +- ...ion_of_elemental_carbon_in_dry_aerosol_particles_in_air.json | 2 +- ...f_elemental_carbon_in_pm10_dry_aerosol_particles_in_air.json | 2 +- ...of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air.json | 2 +- ..._elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_concentration_of_ethane_in_air.json | 2 +- .../standard_name/mass_concentration_of_ethanol_in_air.json | 2 +- .../standard_name/mass_concentration_of_ethene_in_air.json | 2 +- .../standard_name/mass_concentration_of_ethyne_in_air.json | 2 +- ...tration_of_flagellates_expressed_as_carbon_in_sea_water.json | 2 +- ...ation_of_flagellates_expressed_as_nitrogen_in_sea_water.json | 2 +- .../mass_concentration_of_formaldehyde_in_air.json | 2 +- .../standard_name/mass_concentration_of_formic_acid_in_air.json | 2 +- .../mass_concentration_of_fucoxanthin_in_sea_water.json | 2 +- .../mass_concentration_of_gaseous_divalent_mercury_in_air.json | 2 +- .../mass_concentration_of_gaseous_elemental_mercury_in_air.json | 2 +- .../standard_name/mass_concentration_of_halon1202_in_air.json | 2 +- .../standard_name/mass_concentration_of_halon1211_in_air.json | 2 +- .../standard_name/mass_concentration_of_halon1301_in_air.json | 2 +- .../standard_name/mass_concentration_of_halon2402_in_air.json | 2 +- .../standard_name/mass_concentration_of_hcc140a_in_air.json | 2 +- .../standard_name/mass_concentration_of_hcfc141b_in_air.json | 2 +- .../standard_name/mass_concentration_of_hcfc142b_in_air.json | 2 +- .../standard_name/mass_concentration_of_hcfc22_in_air.json | 2 +- .../mass_concentration_of_hexachlorobiphenyl_in_air.json | 2 +- .../mass_concentration_of_hox_expressed_as_hydrogen_in_air.json | 2 +- .../mass_concentration_of_hydrogen_bromide_in_air.json | 2 +- .../mass_concentration_of_hydrogen_chloride_in_air.json | 2 +- .../mass_concentration_of_hydrogen_cyanide_in_air.json | 2 +- .../mass_concentration_of_hydrogen_peroxide_in_air.json | 2 +- .../mass_concentration_of_hydroperoxyl_radical_in_air.json | 2 +- .../mass_concentration_of_hydroxyl_radical_in_air.json | 2 +- .../mass_concentration_of_hypobromous_acid_in_air.json | 2 +- .../mass_concentration_of_hypochlorous_acid_in_air.json | 2 +- .../mass_concentration_of_inorganic_bromine_in_air.json | 2 +- .../mass_concentration_of_inorganic_chlorine_in_air.json | 2 +- .../mass_concentration_of_inorganic_nitrogen_in_sea_water.json | 2 +- .../mass_concentration_of_iron_in_sea_floor_sediment.json | 2 +- .../standard_name/mass_concentration_of_isoprene_in_air.json | 2 +- .../mass_concentration_of_lead_in_sea_floor_sediment.json | 2 +- .../standard_name/mass_concentration_of_limonene_in_air.json | 2 +- .../mass_concentration_of_liquid_water_in_air.json | 2 +- .../mass_concentration_of_lithium_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_lutein_in_sea_water.json | 2 +- .../mass_concentration_of_manganese_in_sea_floor_sediment.json | 2 +- ...s_concentration_of_mercury_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_mercury_in_sea_floor_sediment.json | 2 +- .../standard_name/mass_concentration_of_methane_in_air.json | 2 +- .../standard_name/mass_concentration_of_methanol_in_air.json | 2 +- .../mass_concentration_of_methyl_bromide_in_air.json | 2 +- .../mass_concentration_of_methyl_chloride_in_air.json | 2 +- .../mass_concentration_of_methyl_hydroperoxide_in_air.json | 2 +- .../mass_concentration_of_methyl_peroxy_radical_in_air.json | 2 +- ...icrophytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- ...ous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- .../mass_concentration_of_molecular_hydrogen_in_air.json | 2 +- ...s_concentration_of_monovinyl_chlorophyll_a_in_sea_water.json | 2 +- ...nanophytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- .../mass_concentration_of_nickel_in_sea_floor_sediment.json | 2 +- ...s_concentration_of_nitrate_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_nitrate_radical_in_air.json | 2 +- .../standard_name/mass_concentration_of_nitric_acid_in_air.json | 2 +- ...nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_nitrogen_dioxide_in_air.json | 2 +- .../mass_concentration_of_nitrogen_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_nitrogen_monoxide_in_air.json | 2 +- .../mass_concentration_of_nitrous_acid_in_air.json | 2 +- .../mass_concentration_of_nitrous_oxide_in_air.json | 2 +- .../mass_concentration_of_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../mass_concentration_of_nox_expressed_as_nitrogen_in_air.json | 2 +- .../mass_concentration_of_noy_expressed_as_nitrogen_in_air.json | 2 +- ...ation_of_organic_carbon_in_dry_aerosol_particles_in_air.json | 2 +- ..._of_organic_carbon_in_pm10_dry_aerosol_particles_in_air.json | 2 +- ...n_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air.json | 2 +- ...of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air.json | 2 +- ...s_concentration_of_organic_carbon_in_sea_floor_sediment.json | 2 +- ...on_of_organic_detritus_expressed_as_carbon_in_sea_water.json | 2 +- ..._of_organic_detritus_expressed_as_nitrogen_in_sea_water.json | 2 +- .../mass_concentration_of_oxygen_in_sea_water.json | 2 +- .../mass_concentration_of_oxygenated_hydrocarbons_in_air.json | 2 +- .../standard_name/mass_concentration_of_ozone_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_peridinin_in_sea_water.json | 2 +- .../mass_concentration_of_peroxy_radicals_in_air.json | 2 +- .../mass_concentration_of_peroxyacetyl_nitrate_in_air.json | 2 +- .../mass_concentration_of_peroxynitric_acid_in_air.json | 2 +- ...ss_concentration_of_petroleum_hydrocarbons_in_sea_water.json | 2 +- ...ss_concentration_of_phaeopigments_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_phaeopigments_in_sea_ice.json | 2 +- .../mass_concentration_of_phaeopigments_in_sea_water.json | 2 +- .../mass_concentration_of_phosphate_in_sea_water.json | 2 +- .../mass_concentration_of_phosphorus_in_sea_floor_sediment.json | 2 +- ..._of_phytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- ...picophytoplankton_expressed_as_chlorophyll_in_sea_water.json | 2 +- ..._concentration_of_pm10_ambient_aerosol_particles_in_air.json | 2 +- ...entration_of_pm10_ammonium_dry_aerosol_particles_in_air.json | 2 +- ...centration_of_pm10_bromide_dry_aerosol_particles_in_air.json | 2 +- ...centration_of_pm10_calcium_dry_aerosol_particles_in_air.json | 2 +- ...entration_of_pm10_chloride_dry_aerosol_particles_in_air.json | 2 +- ...ntration_of_pm10_magnesium_dry_aerosol_particles_in_air.json | 2 +- ..._pm10_methanesulfonic_acid_dry_aerosol_particles_in_air.json | 2 +- ...centration_of_pm10_nitrate_dry_aerosol_particles_in_air.json | 2 +- ...centration_of_pm10_oxalate_dry_aerosol_particles_in_air.json | 2 +- ...ntration_of_pm10_potassium_dry_aerosol_particles_in_air.json | 2 +- ..._salt_dry_aerosol_particles_expressed_as_cations_in_air.json | 2 +- ...entration_of_pm10_sea_salt_dry_aerosol_particles_in_air.json | 2 +- ...ncentration_of_pm10_sodium_dry_aerosol_particles_in_air.json | 2 +- ...centration_of_pm10_sulfate_dry_aerosol_particles_in_air.json | 2 +- ...s_concentration_of_pm1_ambient_aerosol_particles_in_air.json | 2 +- ...concentration_of_pm2p5_ambient_aerosol_particles_in_air.json | 2 +- ..._salt_dry_aerosol_particles_expressed_as_cations_in_air.json | 2 +- ...ntration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_prasinoxanthin_in_sea_water.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- ...tration_of_prokaryotes_expressed_as_carbon_in_sea_water.json | 2 +- .../standard_name/mass_concentration_of_propane_in_air.json | 2 +- .../standard_name/mass_concentration_of_propene_in_air.json | 2 +- .../standard_name/mass_concentration_of_radon_in_air.json | 2 +- .../standard_name/mass_concentration_of_rain_in_air.json | 2 +- ..._salt_dry_aerosol_particles_expressed_as_cations_in_air.json | 2 +- ..._concentration_of_sea_salt_dry_aerosol_particles_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_silicate_in_sea_water.json | 2 +- .../mass_concentration_of_silver_in_sea_floor_sediment.json | 2 +- ...ncentration_of_sulfate_ambient_aerosol_particles_in_air.json | 2 +- ...s_concentration_of_sulfate_dry_aerosol_particles_in_air.json | 2 +- .../mass_concentration_of_sulfur_dioxide_in_air.json | 2 +- .../mass_concentration_of_suspended_matter_in_sea_water.json | 2 +- .../standard_name/mass_concentration_of_terpenes_in_air.json | 2 +- .../standard_name/mass_concentration_of_toluene_in_air.json | 2 +- .../mass_concentration_of_vanadium_in_sea_floor_sediment.json | 2 +- .../mass_concentration_of_violaxanthin_in_sea_water.json | 2 +- .../mass_concentration_of_volcanic_ash_in_air.json | 2 +- ...centration_of_water_in_ambient_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_concentration_of_water_vapor_in_air.json | 2 +- .../standard_name/mass_concentration_of_xylene_in_air.json | 2 +- .../mass_concentration_of_zeaxanthin_in_sea_water.json | 2 +- .../mass_concentration_of_zinc_in_sea_floor_sediment.json | 2 +- ...tration_of_zooplankton_expressed_as_carbon_in_sea_water.json | 2 +- ..._litter_and_soil_and_forestry_and_agricultural_products.json | 2 +- ..._litter_and_soil_and_forestry_and_agricultural_products.json | 2 +- ..._litter_and_soil_and_forestry_and_agricultural_products.json | 2 +- ...ss_content_of_cloud_condensed_water_in_atmosphere_layer.json | 2 +- .../mass_content_of_cloud_ice_in_atmosphere_layer.json | 2 +- .../mass_content_of_cloud_liquid_water_in_atmosphere_layer.json | 2 +- ..._litter_and_soil_and_forestry_and_agricultural_products.json | 2 +- .../mass_content_of_water_in_atmosphere_layer.json | 2 +- .../standard_name/mass_content_of_water_in_soil.json | 2 +- .../standard_name/mass_content_of_water_in_soil_layer.json | 2 +- ...ss_content_of_water_in_soil_layer_defined_by_root_depth.json | 2 +- ...ntent_of_water_vapor_containing_17O_in_atmosphere_layer.json | 2 +- ...ntent_of_water_vapor_containing_18O_in_atmosphere_layer.json | 2 +- ...of_water_vapor_containing_single_2H_in_atmosphere_layer.json | 2 +- .../mass_content_of_water_vapor_in_atmosphere_layer.json | 2 +- ...restry_and_agricultural_products_due_to_crop_harvesting.json | 2 +- .../mass_flux_of_carbon_into_litter_from_vegetation.json | 2 +- ..._of_carbon_into_litter_from_vegetation_due_to_mortality.json | 2 +- ...of_carbon_into_litter_from_vegetation_due_to_senescence.json | 2 +- .../mass_flux_of_carbon_into_sea_water_from_rivers.json | 2 +- ...ux_of_carbon_into_soil_from_vegetation_due_to_mortality.json | 2 +- ...x_of_carbon_into_soil_from_vegetation_due_to_senescence.json | 2 +- ...s_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff.json | 2 +- ...en_compounds_expressed_as_nitrogen_into_sea_from_rivers.json | 2 +- ...ter_and_soil_due_to_immobilisation_and_remineralization.json | 2 +- ...getation_and_litter_and_soil_due_to_leaching_and_runoff.json | 2 +- .../standard_name/mass_fraction_of_acetic_acid_in_air.json | 2 +- .../standard_name/mass_fraction_of_aceto_nitrile_in_air.json | 2 +- .../standard_name/mass_fraction_of_alkanes_in_air.json | 2 +- .../standard_name/mass_fraction_of_alkenes_in_air.json | 2 +- .../mass_fraction_of_alpha_hexachlorocyclohexane_in_air.json | 2 +- .../standard_name/mass_fraction_of_alpha_pinene_in_air.json | 2 +- .../standard_name/mass_fraction_of_ammonia_in_air.json | 2 +- .../mass_fraction_of_ammonium_dry_aerosol_particles_in_air.json | 2 +- ...ction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../mass_fraction_of_aromatic_compounds_in_air.json | 2 +- .../standard_name/mass_fraction_of_atomic_bromine_in_air.json | 2 +- .../standard_name/mass_fraction_of_atomic_chlorine_in_air.json | 2 +- .../standard_name/mass_fraction_of_atomic_nitrogen_in_air.json | 2 +- .../standard_name/mass_fraction_of_benzene_in_air.json | 2 +- .../standard_name/mass_fraction_of_beta_pinene_in_air.json | 2 +- ...s_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../standard_name/mass_fraction_of_bromine_chloride_in_air.json | 2 +- .../standard_name/mass_fraction_of_bromine_monoxide_in_air.json | 2 +- .../standard_name/mass_fraction_of_bromine_nitrate_in_air.json | 2 +- .../mass_fraction_of_brox_expressed_as_bromine_in_air.json | 2 +- .../standard_name/mass_fraction_of_butane_in_air.json | 2 +- .../standard_name/mass_fraction_of_carbon_dioxide_in_air.json | 2 +- .../mass_fraction_of_carbon_dioxide_tracer_in_air.json | 2 +- .../standard_name/mass_fraction_of_carbon_monoxide_in_air.json | 2 +- .../mass_fraction_of_carbon_tetrachloride_in_air.json | 2 +- .../standard_name/mass_fraction_of_cfc113_in_air.json | 2 +- .../standard_name/mass_fraction_of_cfc113a_in_air.json | 2 +- .../standard_name/mass_fraction_of_cfc114_in_air.json | 2 +- .../standard_name/mass_fraction_of_cfc115_in_air.json | 2 +- .../standard_name/mass_fraction_of_cfc11_in_air.json | 2 +- .../standard_name/mass_fraction_of_cfc12_in_air.json | 2 +- .../standard_name/mass_fraction_of_chlorine_dioxide_in_air.json | 2 +- .../mass_fraction_of_chlorine_monoxide_in_air.json | 2 +- .../standard_name/mass_fraction_of_chlorine_nitrate_in_air.json | 2 +- .../mass_fraction_of_chlorophyll_a_in_sea_water.json | 2 +- .../standard_name/mass_fraction_of_clay_in_soil.json | 2 +- .../mass_fraction_of_cloud_condensed_water_in_air.json | 2 +- .../standard_name/mass_fraction_of_cloud_ice_in_air.json | 2 +- .../mass_fraction_of_cloud_liquid_water_in_air.json | 2 +- .../mass_fraction_of_clox_expressed_as_chlorine_in_air.json | 2 +- ...ass_fraction_of_convective_cloud_condensed_water_in_air.json | 2 +- .../mass_fraction_of_convective_cloud_ice_in_air.json | 2 +- .../mass_fraction_of_convective_cloud_liquid_water_in_air.json | 2 +- .../mass_fraction_of_dichlorine_peroxide_in_air.json | 2 +- .../standard_name/mass_fraction_of_dimethyl_sulfide_in_air.json | 2 +- .../mass_fraction_of_dinitrogen_pentoxide_in_air.json | 2 +- .../mass_fraction_of_dust_dry_aerosol_particles_in_air.json | 2 +- ...action_of_elemental_carbon_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_ethane_in_air.json | 2 +- .../standard_name/mass_fraction_of_ethanol_in_air.json | 2 +- .../standard_name/mass_fraction_of_ethene_in_air.json | 2 +- .../standard_name/mass_fraction_of_ethyne_in_air.json | 2 +- .../standard_name/mass_fraction_of_formaldehyde_in_air.json | 2 +- .../standard_name/mass_fraction_of_formic_acid_in_air.json | 2 +- .../mass_fraction_of_frozen_water_in_soil_moisture.json | 2 +- .../mass_fraction_of_gaseous_divalent_mercury_in_air.json | 2 +- .../mass_fraction_of_gaseous_elemental_mercury_in_air.json | 2 +- .../standard_name/mass_fraction_of_graupel_and_hail_in_air.json | 2 +- .../standard_name/mass_fraction_of_graupel_in_air.json | 2 +- .../standard_name/mass_fraction_of_gravel_in_soil.json | 2 +- .../standard_name/mass_fraction_of_hail_in_air.json | 2 +- .../standard_name/mass_fraction_of_halon1202_in_air.json | 2 +- .../standard_name/mass_fraction_of_halon1211_in_air.json | 2 +- .../standard_name/mass_fraction_of_halon1301_in_air.json | 2 +- .../standard_name/mass_fraction_of_halon2402_in_air.json | 2 +- .../standard_name/mass_fraction_of_hcc140a_in_air.json | 2 +- .../standard_name/mass_fraction_of_hcfc141b_in_air.json | 2 +- .../standard_name/mass_fraction_of_hcfc142b_in_air.json | 2 +- .../standard_name/mass_fraction_of_hcfc22_in_air.json | 2 +- .../mass_fraction_of_hexachlorobiphenyl_in_air.json | 2 +- .../mass_fraction_of_hox_expressed_as_hydrogen_in_air.json | 2 +- .../standard_name/mass_fraction_of_hydrogen_bromide_in_air.json | 2 +- .../mass_fraction_of_hydrogen_chloride_in_air.json | 2 +- .../standard_name/mass_fraction_of_hydrogen_cyanide_in_air.json | 2 +- .../mass_fraction_of_hydrogen_peroxide_in_air.json | 2 +- .../mass_fraction_of_hydroperoxyl_radical_in_air.json | 2 +- .../standard_name/mass_fraction_of_hydroxyl_radical_in_air.json | 2 +- .../standard_name/mass_fraction_of_hypobromous_acid_in_air.json | 2 +- .../mass_fraction_of_hypochlorous_acid_in_air.json | 2 +- .../mass_fraction_of_inorganic_bromine_in_air.json | 2 +- .../mass_fraction_of_inorganic_chlorine_in_air.json | 2 +- .../standard_name/mass_fraction_of_isoprene_in_air.json | 2 +- .../standard_name/mass_fraction_of_limonene_in_air.json | 2 +- .../mass_fraction_of_liquid_precipitation_in_air.json | 2 +- .../mass_fraction_of_mercury_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_methane_in_air.json | 2 +- ...on_of_methanesulfonic_acid_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_methanol_in_air.json | 2 +- .../standard_name/mass_fraction_of_methyl_bromide_in_air.json | 2 +- .../standard_name/mass_fraction_of_methyl_chloride_in_air.json | 2 +- .../mass_fraction_of_methyl_hydroperoxide_in_air.json | 2 +- .../mass_fraction_of_methyl_peroxy_radical_in_air.json | 2 +- .../mass_fraction_of_molecular_hydrogen_in_air.json | 2 +- .../mass_fraction_of_nitrate_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_nitrate_radical_in_air.json | 2 +- .../standard_name/mass_fraction_of_nitric_acid_in_air.json | 2 +- ...nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_nitrogen_dioxide_in_air.json | 2 +- .../mass_fraction_of_nitrogen_monoxide_in_air.json | 2 +- .../standard_name/mass_fraction_of_nitrous_acid_in_air.json | 2 +- .../standard_name/mass_fraction_of_nitrous_oxide_in_air.json | 2 +- .../mass_fraction_of_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../mass_fraction_of_nox_expressed_as_nitrogen_in_air.json | 2 +- .../mass_fraction_of_noy_expressed_as_nitrogen_in_air.json | 2 +- .../standard_name/mass_fraction_of_organic_matter_in_soil.json | 2 +- .../mass_fraction_of_oxygenated_hydrocarbons_in_air.json | 2 +- .../standard_name/mass_fraction_of_ozone_in_air.json | 2 +- ...matter_dry_aerosol_particles_expressed_as_carbon_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_peroxy_radicals_in_air.json | 2 +- .../mass_fraction_of_peroxyacetyl_nitrate_in_air.json | 2 +- .../mass_fraction_of_peroxynitric_acid_in_air.json | 2 +- .../mass_fraction_of_pm10_ambient_aerosol_particles_in_air.json | 2 +- ..._fraction_of_pm10_ammonium_dry_aerosol_particles_in_air.json | 2 +- .../mass_fraction_of_pm10_dry_aerosol_particles_in_air.json | 2 +- ...mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air.json | 2 +- ...n_of_pm10_elemental_carbon_dry_aerosol_particles_in_air.json | 2 +- ...s_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air.json | 2 +- ...matter_dry_aerosol_particles_expressed_as_carbon_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- ..._salt_dry_aerosol_particles_expressed_as_cations_in_air.json | 2 +- ..._fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air.json | 2 +- ...s_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air.json | 2 +- .../mass_fraction_of_pm1_ambient_aerosol_particles_in_air.json | 2 +- .../mass_fraction_of_pm1_dry_aerosol_particles_in_air.json | 2 +- ...mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air.json | 2 +- ...fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air.json | 2 +- .../mass_fraction_of_pm2p5_dry_aerosol_particles_in_air.json | 2 +- ...ass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air.json | 2 +- ..._of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air.json | 2 +- ..._fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air.json | 2 +- ...matter_dry_aerosol_particles_expressed_as_carbon_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- ..._salt_dry_aerosol_particles_expressed_as_cations_in_air.json | 2 +- ...fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json | 2 +- ..._fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_precipitation_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_propane_in_air.json | 2 +- .../standard_name/mass_fraction_of_propene_in_air.json | 2 +- .../standard_name/mass_fraction_of_radon_in_air.json | 2 +- .../mass_fraction_of_rainfall_falling_onto_surface_snow.json | 2 +- .../standard_name/mass_fraction_of_sand_in_soil.json | 2 +- ..._salt_dry_aerosol_particles_expressed_as_cations_in_air.json | 2 +- .../mass_fraction_of_sea_salt_dry_aerosol_particles_in_air.json | 2 +- ...particulate_organic_matter_dry_aerosol_particles_in_air.json | 2 +- ...raction_of_shallow_convective_cloud_liquid_water_in_air.json | 2 +- .../standard_name/mass_fraction_of_silt_in_soil.json | 2 +- .../standard_name/mass_fraction_of_snow_in_air.json | 2 +- ...action_of_solid_precipitation_falling_onto_surface_snow.json | 2 +- .../mass_fraction_of_stratiform_cloud_ice_in_air.json | 2 +- .../mass_fraction_of_stratiform_cloud_liquid_water_in_air.json | 2 +- .../mass_fraction_of_sulfate_dry_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_sulfur_dioxide_in_air.json | 2 +- .../standard_name/mass_fraction_of_sulfuric_acid_in_air.json | 2 +- .../standard_name/mass_fraction_of_terpenes_in_air.json | 2 +- .../standard_name/mass_fraction_of_toluene_in_air.json | 2 +- .../mass_fraction_of_unfrozen_water_in_soil_moisture.json | 2 +- .../standard_name/mass_fraction_of_water_in_air.json | 2 +- ...s_fraction_of_water_in_ambient_aerosol_particles_in_air.json | 2 +- ...ction_of_water_in_pm10_ambient_aerosol_particles_in_air.json | 2 +- ...tion_of_water_in_pm2p5_ambient_aerosol_particles_in_air.json | 2 +- .../standard_name/mass_fraction_of_xylene_in_air.json | 2 +- .../standard_name/mass_ratio_of_moisture_to_dry_soil.json | 2 +- ...dinate_rotation_of_sea_ice_horizontal_shear_strain_rate.json | 2 +- ..._coordinate_rotation_of_sea_ice_horizontal_shear_stress.json | 2 +- .../standard_name/medium_soil_pool_mass_content_of_carbon.json | 2 +- .../standard_name/medium_type_cloud_area_fraction.json | 2 +- ...minimum_depth_of_aragonite_undersaturation_in_sea_water.json | 2 +- .../minimum_depth_of_calcite_undersaturation_in_sea_water.json | 2 +- ...ss_ratio_of_water_to_dry_soil_for_soil_plastic_behavior.json | 2 +- ...m_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow.json | 2 +- .../minus_one_times_surface_upwelling_longwave_flux_in_air.json | 2 +- ...minus_one_times_surface_upwelling_shortwave_flux_in_air.json | 2 +- .../minus_one_times_toa_outgoing_shortwave_flux.json | 2 +- .../minus_one_times_water_flux_into_sea_water_from_rivers.json | 2 +- ...tmosphere_mass_content_of_ammonia_due_to_dry_deposition.json | 2 +- ...tmosphere_mass_content_of_ammonia_due_to_wet_deposition.json | 2 +- ...of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json | 2 +- ...of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json | 2 +- ...content_of_dust_dry_aerosol_particles_due_to_deposition.json | 2 +- ...ent_of_dust_dry_aerosol_particles_due_to_dry_deposition.json | 2 +- ...ent_of_dust_dry_aerosol_particles_due_to_wet_deposition.json | 2 +- ...ntal_carbon_dry_aerosol_particles_due_to_dry_deposition.json | 2 +- ...ntal_carbon_dry_aerosol_particles_due_to_wet_deposition.json | 2 +- ..._insoluble_dust_dry_aerosol_particles_due_to_deposition.json | 2 +- ...rogen_compounds_expressed_as_nitrogen_due_to_deposition.json | 2 +- ...tent_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json | 2 +- ...tent_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json | 2 +- ..._atmosphere_mass_content_of_ozone_due_to_dry_deposition.json | 2 +- ...anic_matter_dry_aerosol_particles_due_to_dry_deposition.json | 2 +- ...anic_matter_dry_aerosol_particles_due_to_wet_deposition.json | 2 +- ...of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json | 2 +- ...of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json | 2 +- ..._of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json | 2 +- ..._of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json | 2 +- ...re_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json | 2 +- ...re_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json | 2 +- ...ental_nitrogen_due_to_denitrification_and_sedimentation.json | 2 +- ...n_mole_content_of_inorganic_carbon_due_to_sedimentation.json | 2 +- ...ency_of_ocean_mole_content_of_iron_due_to_sedimentation.json | 2 +- ...ean_mole_content_of_organic_carbon_due_to_sedimentation.json | 2 +- .../miscellaneous_living_matter_mass_content_of_carbon.json | 2 +- .../miscellaneous_living_matter_mass_content_of_nitrogen.json | 2 +- data_descriptors/standard_name/model_level_number.json | 2 +- ...ber_at_base_of_ocean_mixed_layer_defined_by_sigma_theta.json | 2 +- .../model_level_number_at_convective_cloud_base.json | 2 +- .../model_level_number_at_convective_cloud_top.json | 2 +- .../standard_name/model_level_number_at_sea_floor.json | 2 +- .../model_level_number_at_top_of_atmosphere_boundary_layer.json | 2 +- .../standard_name/modified_fosberg_fire_weather_index.json | 2 +- data_descriptors/standard_name/modis_cloud_area_fraction.json | 2 +- .../standard_name/modis_ice_topped_cloud_area_fraction.json | 2 +- .../standard_name/modis_liquid_topped_cloud_area_fraction.json | 2 +- .../moisture_content_of_soil_layer_at_field_capacity.json | 2 +- .../standard_name/mole_concentration_of_acetic_acid_in_air.json | 2 +- .../mole_concentration_of_aceto_nitrile_in_air.json | 2 +- ...le_concentration_of_adenosine_triphosphate_in_sea_water.json | 2 +- ...ole_concentration_of_alpha_hexachlorocyclohexane_in_air.json | 2 +- .../mole_concentration_of_alpha_pinene_in_air.json | 2 +- .../standard_name/mole_concentration_of_ammonia_in_air.json | 2 +- .../mole_concentration_of_ammonium_in_sea_water.json | 2 +- ...ation_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- ...entration_of_aragonite_expressed_as_carbon_in_sea_water.json | 2 +- ...ragonite_expressed_as_carbon_in_sea_water_at_saturation.json | 2 +- .../mole_concentration_of_atomic_bromine_in_air.json | 2 +- .../mole_concentration_of_atomic_chlorine_in_air.json | 2 +- .../mole_concentration_of_atomic_nitrogen_in_air.json | 2 +- ...centration_of_bacteria_expressed_as_carbon_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_benzene_in_air.json | 2 +- .../standard_name/mole_concentration_of_beta_pinene_in_air.json | 2 +- ...centration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- ...on_of_biological_taxon_expressed_as_carbon_in_sea_water.json | 2 +- ..._of_biological_taxon_expressed_as_nitrogen_in_sea_water.json | 2 +- .../mole_concentration_of_bromine_chloride_in_air.json | 2 +- .../mole_concentration_of_bromine_monoxide_in_air.json | 2 +- .../mole_concentration_of_bromine_nitrate_in_air.json | 2 +- .../mole_concentration_of_brox_expressed_as_bromine_in_air.json | 2 +- .../standard_name/mole_concentration_of_butane_in_air.json | 2 +- ...lcareous_phytoplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...ncentration_of_calcite_expressed_as_carbon_in_sea_water.json | 2 +- ..._calcite_expressed_as_carbon_in_sea_water_at_saturation.json | 2 +- .../mole_concentration_of_carbon_dioxide_in_air.json | 2 +- .../mole_concentration_of_carbon_monoxide_in_air.json | 2 +- .../mole_concentration_of_carbon_tetrachloride_in_air.json | 2 +- ...onate_abiotic_analogue_expressed_as_carbon_in_sea_water.json | 2 +- ..._carbon_at_equilibrium_with_pure_aragonite_in_sea_water.json | 2 +- ...as_carbon_at_equilibrium_with_pure_calcite_in_sea_water.json | 2 +- ...entration_of_carbonate_expressed_as_carbon_in_sea_water.json | 2 +- ...onate_natural_analogue_expressed_as_carbon_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_cfc113_in_air.json | 2 +- .../standard_name/mole_concentration_of_cfc113a_in_air.json | 2 +- .../standard_name/mole_concentration_of_cfc114_in_air.json | 2 +- .../standard_name/mole_concentration_of_cfc115_in_air.json | 2 +- .../standard_name/mole_concentration_of_cfc11_in_air.json | 2 +- .../standard_name/mole_concentration_of_cfc11_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_cfc12_in_air.json | 2 +- .../standard_name/mole_concentration_of_cfc12_in_sea_water.json | 2 +- .../mole_concentration_of_chlorine_dioxide_in_air.json | 2 +- .../mole_concentration_of_chlorine_monoxide_in_air.json | 2 +- .../mole_concentration_of_chlorine_nitrate_in_air.json | 2 +- ...mole_concentration_of_clox_expressed_as_chlorine_in_air.json | 2 +- ...ncentration_of_diatoms_expressed_as_carbon_in_sea_water.json | 2 +- ...entration_of_diatoms_expressed_as_nitrogen_in_sea_water.json | 2 +- ...otrophic_phytoplankton_expressed_as_carbon_in_sea_water.json | 2 +- .../mole_concentration_of_dichlorine_peroxide_in_air.json | 2 +- .../mole_concentration_of_dimethyl_sulfide_in_air.json | 2 +- .../mole_concentration_of_dimethyl_sulfide_in_sea_water.json | 2 +- .../mole_concentration_of_dinitrogen_pentoxide_in_air.json | 2 +- ...e_concentration_of_dissolved_inorganic_13C_in_sea_water.json | 2 +- ...e_concentration_of_dissolved_inorganic_14C_in_sea_water.json | 2 +- ...issolved_inorganic_carbon_abiotic_analogue_in_sea_water.json | 2 +- ...olved_inorganic_carbon_in_sea_floor_sediment_pore_water.json | 2 +- ...oncentration_of_dissolved_inorganic_carbon_in_sea_water.json | 2 +- ...issolved_inorganic_carbon_natural_analogue_in_sea_water.json | 2 +- ...centration_of_dissolved_inorganic_nitrogen_in_sea_water.json | 2 +- ...ntration_of_dissolved_inorganic_phosphorus_in_sea_water.json | 2 +- ...ncentration_of_dissolved_inorganic_silicon_in_sea_water.json | 2 +- .../mole_concentration_of_dissolved_iron_in_sea_water.json | 2 +- ...centration_of_dissolved_molecular_nitrogen_in_sea_water.json | 2 +- ...oncentration_of_dissolved_molecular_oxygen_in_sea_water.json | 2 +- ...f_dissolved_molecular_oxygen_in_sea_water_at_saturation.json | 2 +- ...a_water_at_shallowest_local_minimum_in_vertical_profile.json | 2 +- .../mole_concentration_of_dissolved_nitrogen_in_sea_water.json | 2 +- ...ole_concentration_of_dissolved_organic_13C_in_sea_water.json | 2 +- ...ssolved_organic_carbon_in_sea_floor_sediment_pore_water.json | 2 +- ..._concentration_of_dissolved_organic_carbon_in_sea_water.json | 2 +- ...oncentration_of_dissolved_organic_nitrogen_in_sea_water.json | 2 +- ...centration_of_dissolved_organic_phosphorus_in_sea_water.json | 2 +- ...mole_concentration_of_dissolved_phosphorus_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_ethane_in_air.json | 2 +- .../standard_name/mole_concentration_of_ethanol_in_air.json | 2 +- .../standard_name/mole_concentration_of_ethene_in_air.json | 2 +- .../standard_name/mole_concentration_of_ethyne_in_air.json | 2 +- .../mole_concentration_of_formaldehyde_in_air.json | 2 +- .../standard_name/mole_concentration_of_formic_acid_in_air.json | 2 +- .../mole_concentration_of_gaseous_divalent_mercury_in_air.json | 2 +- .../mole_concentration_of_gaseous_elemental_mercury_in_air.json | 2 +- ...le_concentration_of_guanosine_triphosphate_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_halon1202_in_air.json | 2 +- .../standard_name/mole_concentration_of_halon1211_in_air.json | 2 +- .../standard_name/mole_concentration_of_halon1301_in_air.json | 2 +- .../standard_name/mole_concentration_of_halon2402_in_air.json | 2 +- .../standard_name/mole_concentration_of_hcc140a_in_air.json | 2 +- .../standard_name/mole_concentration_of_hcfc141b_in_air.json | 2 +- .../standard_name/mole_concentration_of_hcfc142b_in_air.json | 2 +- .../standard_name/mole_concentration_of_hcfc22_in_air.json | 2 +- .../mole_concentration_of_hexachlorobiphenyl_in_air.json | 2 +- .../mole_concentration_of_hox_expressed_as_hydrogen_in_air.json | 2 +- .../mole_concentration_of_hydrogen_bromide_in_air.json | 2 +- .../mole_concentration_of_hydrogen_chloride_in_air.json | 2 +- .../mole_concentration_of_hydrogen_cyanide_in_air.json | 2 +- .../mole_concentration_of_hydrogen_peroxide_in_air.json | 2 +- .../mole_concentration_of_hydrogen_sulfide_in_sea_water.json | 2 +- .../mole_concentration_of_hydroperoxyl_radical_in_air.json | 2 +- .../mole_concentration_of_hydroxyl_radical_in_air.json | 2 +- .../mole_concentration_of_hypobromous_acid_in_air.json | 2 +- .../mole_concentration_of_hypochlorous_acid_in_air.json | 2 +- .../mole_concentration_of_inorganic_bromine_in_air.json | 2 +- .../mole_concentration_of_inorganic_chlorine_in_air.json | 2 +- .../standard_name/mole_concentration_of_isoprene_in_air.json | 2 +- .../standard_name/mole_concentration_of_limonene_in_air.json | 2 +- ...ion_of_mesozooplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...n_of_mesozooplankton_expressed_as_nitrogen_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_methane_in_air.json | 2 +- .../standard_name/mole_concentration_of_methanol_in_air.json | 2 +- .../mole_concentration_of_methyl_bromide_in_air.json | 2 +- .../mole_concentration_of_methyl_chloride_in_air.json | 2 +- .../mole_concentration_of_methyl_hydroperoxide_in_air.json | 2 +- .../mole_concentration_of_methyl_peroxy_radical_in_air.json | 2 +- ...on_of_microzooplankton_expressed_as_carbon_in_sea_water.json | 2 +- ..._of_microzooplankton_expressed_as_nitrogen_in_sea_water.json | 2 +- ...llaneous_phytoplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...cellaneous_zooplankton_expressed_as_carbon_in_sea_water.json | 2 +- .../mole_concentration_of_molecular_hydrogen_in_air.json | 2 +- .../mole_concentration_of_nitrate_and_nitrite_in_sea_water.json | 2 +- .../mole_concentration_of_nitrate_in_sea_water.json | 2 +- .../mole_concentration_of_nitrate_radical_in_air.json | 2 +- .../standard_name/mole_concentration_of_nitric_acid_in_air.json | 2 +- ...nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json | 2 +- .../mole_concentration_of_nitrite_in_sea_water.json | 2 +- .../mole_concentration_of_nitrogen_dioxide_in_air.json | 2 +- .../mole_concentration_of_nitrogen_monoxide_in_air.json | 2 +- .../mole_concentration_of_nitrous_acid_in_air.json | 2 +- .../mole_concentration_of_nitrous_oxide_in_air.json | 2 +- .../mole_concentration_of_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../mole_concentration_of_nox_expressed_as_nitrogen_in_air.json | 2 +- .../mole_concentration_of_noy_expressed_as_nitrogen_in_air.json | 2 +- ...on_of_organic_detritus_expressed_as_carbon_in_sea_water.json | 2 +- ..._of_organic_detritus_expressed_as_nitrogen_in_sea_water.json | 2 +- ...n_of_organic_detritus_expressed_as_silicon_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_ozone_in_air.json | 2 +- ...of_particulate_matter_expressed_as_calcium_in_sea_water.json | 2 +- ..._of_particulate_matter_expressed_as_carbon_in_sea_water.json | 2 +- ...on_of_particulate_matter_expressed_as_iron_in_sea_water.json | 2 +- ..._particulate_matter_expressed_as_magnesium_in_sea_water.json | 2 +- ..._particulate_matter_expressed_as_manganese_in_sea_water.json | 2 +- ...particulate_matter_expressed_as_phosphorus_in_sea_water.json | 2 +- ..._particulate_matter_expressed_as_potassium_in_sea_water.json | 2 +- ...of_particulate_matter_expressed_as_silicon_in_sea_water.json | 2 +- ..._of_particulate_matter_expressed_as_sodium_in_sea_water.json | 2 +- ..._of_particulate_matter_expressed_as_sulfur_in_sea_water.json | 2 +- ...on_of_particulate_matter_expressed_as_zinc_in_sea_water.json | 2 +- ...rticulate_organic_matter_expressed_as_iron_in_sea_water.json | 2 +- ...ulate_organic_matter_expressed_as_nitrogen_in_sea_water.json | 2 +- ...ate_organic_matter_expressed_as_phosphorus_in_sea_water.json | 2 +- ...culate_organic_matter_expressed_as_silicon_in_sea_water.json | 2 +- ...centration_of_particulate_organic_nitrogen_in_sea_water.json | 2 +- .../mole_concentration_of_peroxyacetyl_nitrate_in_air.json | 2 +- .../mole_concentration_of_peroxynitric_acid_in_air.json | 2 +- .../mole_concentration_of_phosphate_in_sea_water.json | 2 +- ...ation_of_phytoplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...tration_of_phytoplankton_expressed_as_iron_in_sea_water.json | 2 +- ...ion_of_phytoplankton_expressed_as_nitrogen_in_sea_water.json | 2 +- ...n_of_phytoplankton_expressed_as_phosphorus_in_sea_water.json | 2 +- ...tion_of_phytoplankton_expressed_as_silicon_in_sea_water.json | 2 +- ...n_of_picophytoplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...ation_of_preformed_dissolved_inorganic_13C_in_sea_water.json | 2 +- ...on_of_preformed_dissolved_inorganic_carbon_in_sea_water.json | 2 +- ...f_preformed_dissolved_inorganic_phosphorus_in_sea_water.json | 2 +- ...on_of_preformed_dissolved_molecular_oxygen_in_sea_water.json | 2 +- ...tration_of_prokaryotes_expressed_as_carbon_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_propane_in_air.json | 2 +- .../standard_name/mole_concentration_of_propene_in_air.json | 2 +- .../standard_name/mole_concentration_of_radon_in_air.json | 2 +- .../mole_concentration_of_silicate_in_sea_water.json | 2 +- .../mole_concentration_of_sulfur_dioxide_in_air.json | 2 +- .../mole_concentration_of_sulfur_hexafluoride_in_sea_water.json | 2 +- .../standard_name/mole_concentration_of_toluene_in_air.json | 2 +- .../standard_name/mole_concentration_of_water_vapor_in_air.json | 2 +- .../standard_name/mole_concentration_of_xylene_in_air.json | 2 +- ...tration_of_zooplankton_expressed_as_carbon_in_sea_water.json | 2 +- ...ation_of_zooplankton_expressed_as_nitrogen_in_sea_water.json | 2 +- .../mole_content_of_carbon_monoxide_in_atmosphere_layer.json | 2 +- .../mole_content_of_methane_in_atmosphere_layer.json | 2 +- .../mole_content_of_nitrogen_dioxide_in_atmosphere_layer.json | 2 +- .../mole_content_of_ozone_in_atmosphere_layer.json | 2 +- .../standard_name/mole_fraction_of_acetaldehyde_in_air.json | 2 +- .../standard_name/mole_fraction_of_acetic_acid_in_air.json | 2 +- .../standard_name/mole_fraction_of_aceto_nitrile_in_air.json | 2 +- .../standard_name/mole_fraction_of_acetone_in_air.json | 2 +- .../standard_name/mole_fraction_of_aldehydes_in_air.json | 2 +- .../standard_name/mole_fraction_of_alkanes_in_air.json | 2 +- .../standard_name/mole_fraction_of_alkenes_in_air.json | 2 +- .../mole_fraction_of_alpha_hexachlorocyclohexane_in_air.json | 2 +- .../standard_name/mole_fraction_of_alpha_pinene_in_air.json | 2 +- .../standard_name/mole_fraction_of_ammonia_in_air.json | 2 +- ...ction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- ...raction_of_artificial_tracer_with_fixed_lifetime_in_air.json | 2 +- .../standard_name/mole_fraction_of_atomic_bromine_in_air.json | 2 +- .../standard_name/mole_fraction_of_atomic_chlorine_in_air.json | 2 +- .../standard_name/mole_fraction_of_atomic_nitrogen_in_air.json | 2 +- .../standard_name/mole_fraction_of_benzene_in_air.json | 2 +- .../standard_name/mole_fraction_of_beta_pinene_in_air.json | 2 +- ...e_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../standard_name/mole_fraction_of_bromine_chloride_in_air.json | 2 +- .../standard_name/mole_fraction_of_bromine_monoxide_in_air.json | 2 +- .../standard_name/mole_fraction_of_bromine_nitrate_in_air.json | 2 +- .../mole_fraction_of_bromochloromethane_in_air.json | 2 +- .../mole_fraction_of_bromodichloromethane_in_air.json | 2 +- .../mole_fraction_of_brox_expressed_as_bromine_in_air.json | 2 +- .../standard_name/mole_fraction_of_butane_in_air.json | 2 +- .../standard_name/mole_fraction_of_carbon_dioxide_in_air.json | 2 +- .../mole_fraction_of_carbon_dioxide_in_dry_air.json | 2 +- .../standard_name/mole_fraction_of_carbon_monoxide_in_air.json | 2 +- .../mole_fraction_of_carbon_monoxide_in_dry_air.json | 2 +- .../mole_fraction_of_carbon_tetrachloride_in_air.json | 2 +- .../mole_fraction_of_carbon_tetrafluoride_in_air.json | 2 +- .../mole_fraction_of_carbonyl_fluoride_in_air.json | 2 +- .../standard_name/mole_fraction_of_carbonyl_sulfide_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc113_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc113a_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc114_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc115_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc11_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc12_in_air.json | 2 +- .../standard_name/mole_fraction_of_cfc13_in_air.json | 2 +- .../standard_name/mole_fraction_of_chlorine_dioxide_in_air.json | 2 +- .../mole_fraction_of_chlorine_monoxide_in_air.json | 2 +- .../standard_name/mole_fraction_of_chlorine_nitrate_in_air.json | 2 +- .../standard_name/mole_fraction_of_chloroform_in_air.json | 2 +- .../mole_fraction_of_clox_expressed_as_chlorine_in_air.json | 2 +- .../mole_fraction_of_dibromochloromethane_in_air.json | 2 +- .../standard_name/mole_fraction_of_dibromomethane_in_air.json | 2 +- .../standard_name/mole_fraction_of_dichlorine_in_air.json | 2 +- .../mole_fraction_of_dichlorine_peroxide_in_air.json | 2 +- .../standard_name/mole_fraction_of_dichloromethane_in_air.json | 2 +- .../standard_name/mole_fraction_of_dimethyl_sulfide_in_air.json | 2 +- .../mole_fraction_of_dinitrogen_pentoxide_in_air.json | 2 +- .../standard_name/mole_fraction_of_ethane_in_air.json | 2 +- .../standard_name/mole_fraction_of_ethanol_in_air.json | 2 +- .../standard_name/mole_fraction_of_ethene_in_air.json | 2 +- .../standard_name/mole_fraction_of_ethyne_in_air.json | 2 +- .../standard_name/mole_fraction_of_formaldehyde_in_air.json | 2 +- .../standard_name/mole_fraction_of_formic_acid_in_air.json | 2 +- .../mole_fraction_of_gaseous_divalent_mercury_in_air.json | 2 +- .../mole_fraction_of_gaseous_elemental_mercury_in_air.json | 2 +- .../standard_name/mole_fraction_of_glyoxal_in_air.json | 2 +- .../standard_name/mole_fraction_of_halon1202_in_air.json | 2 +- .../standard_name/mole_fraction_of_halon1211_in_air.json | 2 +- .../standard_name/mole_fraction_of_halon1301_in_air.json | 2 +- .../standard_name/mole_fraction_of_halon2402_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcc140a_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcfc124_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcfc132b_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcfc133a_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcfc141b_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcfc142b_in_air.json | 2 +- .../standard_name/mole_fraction_of_hcfc22_in_air.json | 2 +- .../mole_fraction_of_hexachlorobiphenyl_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc125_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc134a_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc143a_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc152a_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc227ea_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc236fa_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc23_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc245fa_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc32_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc365mfc_in_air.json | 2 +- .../standard_name/mole_fraction_of_hfc4310mee_in_air.json | 2 +- .../mole_fraction_of_hox_expressed_as_hydrogen_in_air.json | 2 +- .../standard_name/mole_fraction_of_hydrogen_bromide_in_air.json | 2 +- .../mole_fraction_of_hydrogen_chloride_in_air.json | 2 +- .../standard_name/mole_fraction_of_hydrogen_cyanide_in_air.json | 2 +- .../mole_fraction_of_hydrogen_peroxide_in_air.json | 2 +- .../standard_name/mole_fraction_of_hydrogen_sulfide_in_air.json | 2 +- .../mole_fraction_of_hydroperoxyl_radical_in_air.json | 2 +- .../standard_name/mole_fraction_of_hydroxyl_radical_in_air.json | 2 +- .../standard_name/mole_fraction_of_hypobromous_acid_in_air.json | 2 +- .../mole_fraction_of_hypochlorous_acid_in_air.json | 2 +- .../mole_fraction_of_inorganic_bromine_in_air.json | 2 +- .../mole_fraction_of_inorganic_chlorine_in_air.json | 2 +- .../standard_name/mole_fraction_of_isoprene_in_air.json | 2 +- .../standard_name/mole_fraction_of_limonene_in_air.json | 2 +- .../standard_name/mole_fraction_of_methane_in_air.json | 2 +- .../standard_name/mole_fraction_of_methane_in_dry_air.json | 2 +- .../standard_name/mole_fraction_of_methanol_in_air.json | 2 +- .../standard_name/mole_fraction_of_methyl_bromide_in_air.json | 2 +- .../standard_name/mole_fraction_of_methyl_chloride_in_air.json | 2 +- .../mole_fraction_of_methyl_hydroperoxide_in_air.json | 2 +- .../mole_fraction_of_methyl_peroxy_radical_in_air.json | 2 +- .../standard_name/mole_fraction_of_methylglyoxal_in_air.json | 2 +- .../mole_fraction_of_molecular_hydrogen_in_air.json | 2 +- .../standard_name/mole_fraction_of_nitrate_radical_in_air.json | 2 +- .../standard_name/mole_fraction_of_nitric_acid_in_air.json | 2 +- ...nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json | 2 +- .../standard_name/mole_fraction_of_nitrogen_dioxide_in_air.json | 2 +- .../mole_fraction_of_nitrogen_monoxide_in_air.json | 2 +- .../mole_fraction_of_nitrogen_trifluoride_in_air.json | 2 +- .../standard_name/mole_fraction_of_nitrous_acid_in_air.json | 2 +- .../standard_name/mole_fraction_of_nitrous_oxide_in_air.json | 2 +- .../mole_fraction_of_nitrous_oxide_in_dry_air.json | 2 +- .../mole_fraction_of_nmvoc_expressed_as_carbon_in_air.json | 2 +- .../mole_fraction_of_nox_expressed_as_nitrogen_in_air.json | 2 +- .../mole_fraction_of_noy_expressed_as_nitrogen_in_air.json | 2 +- .../standard_name/mole_fraction_of_organic_nitrates_in_air.json | 2 +- data_descriptors/standard_name/mole_fraction_of_ox_in_air.json | 2 +- .../standard_name/mole_fraction_of_ozone_in_air.json | 2 +- .../standard_name/mole_fraction_of_perchloroethene_in_air.json | 2 +- .../mole_fraction_of_peroxyacetyl_nitrate_in_air.json | 2 +- .../mole_fraction_of_peroxynitric_acid_in_air.json | 2 +- .../standard_name/mole_fraction_of_pfc116_in_air.json | 2 +- .../standard_name/mole_fraction_of_pfc218_in_air.json | 2 +- .../standard_name/mole_fraction_of_pfc318_in_air.json | 2 +- .../standard_name/mole_fraction_of_propane_in_air.json | 2 +- .../standard_name/mole_fraction_of_propene_in_air.json | 2 +- .../standard_name/mole_fraction_of_radon_in_air.json | 2 +- .../standard_name/mole_fraction_of_sulfur_dioxide_in_air.json | 2 +- .../mole_fraction_of_sulfur_hexafluoride_in_air.json | 2 +- .../mole_fraction_of_sulfuryl_fluoride_in_air.json | 2 +- .../standard_name/mole_fraction_of_toluene_in_air.json | 2 +- .../standard_name/mole_fraction_of_tribromomethane_in_air.json | 2 +- .../standard_name/mole_fraction_of_water_vapor_in_air.json | 2 +- .../standard_name/mole_fraction_of_xylene_in_air.json | 2 +- .../mole_ratio_of_nitrate_to_phosphate_in_sea_water.json | 2 +- ...es_of_adenosine_triphosphate_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_ammonium_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_cfc11_per_unit_mass_in_sea_water.json | 2 +- ...f_dissolved_inorganic_carbon_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water.json | 2 +- ..._of_dissolved_organic_carbon_per_unit_mass_in_sea_water.json | 2 +- ...f_dissolved_organic_nitrogen_per_unit_mass_in_sea_water.json | 2 +- ...dissolved_organic_phosphorus_per_unit_mass_in_sea_water.json | 2 +- ...oles_of_dissolved_phosphorus_per_unit_mass_in_sea_water.json | 2 +- ...es_of_guanosine_triphosphate_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water.json | 2 +- ...moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_nitrate_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_nitrite_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_nitrous_oxide_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_oxygen_per_unit_mass_in_sea_water.json | 2 +- ..._particulate_biogenic_silica_per_unit_mass_in_sea_water.json | 2 +- ...particulate_inorganic_carbon_per_unit_mass_in_sea_water.json | 2 +- ...e_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json | 2 +- ...matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json | 2 +- ...tter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json | 2 +- ...c_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json | 2 +- ...matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json | 2 +- ...tter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_phosphate_per_unit_mass_in_sea_water.json | 2 +- .../moles_of_silicate_per_unit_mass_in_sea_water.json | 2 +- ...moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water.json | 2 +- .../standard_name/multi_variate_test_quality_flag.json | 2 +- data_descriptors/standard_name/neighbor_test_quality_flag.json | 2 +- .../standard_name/net_downward_longwave_flux_in_air.json | 2 +- .../net_downward_longwave_flux_in_air_assuming_clear_sky.json | 2 +- .../net_downward_radiative_flux_at_top_of_atmosphere_model.json | 2 +- .../net_downward_shortwave_flux_at_sea_water_surface.json | 2 +- .../standard_name/net_downward_shortwave_flux_in_air.json | 2 +- .../net_downward_shortwave_flux_in_air_assuming_clear_sky.json | 2 +- ...biomass_expressed_as_carbon_by_calcareous_phytoplankton.json | 2 +- ..._productivity_of_biomass_expressed_as_carbon_by_diatoms.json | 2 +- ...omass_expressed_as_carbon_by_diazotrophic_phytoplankton.json | 2 +- ...mass_expressed_as_carbon_by_miscellaneous_phytoplankton.json | 2 +- ...ctivity_of_biomass_expressed_as_carbon_by_phytoplankton.json | 2 +- ...ity_of_biomass_expressed_as_carbon_by_picophytoplankton.json | 2 +- ..._biomass_expressed_as_carbon_due_to_nitrate_utilization.json | 2 +- ...iomass_expressed_as_carbon_per_unit_volume_in_sea_water.json | 2 +- ...net_primary_productivity_of_biomass_expressed_as_carbon.json | 2 +- ...ty_of_biomass_expressed_as_carbon_accumulated_in_leaves.json | 2 +- ...ed_as_carbon_accumulated_in_miscellaneous_living_matter.json | 2 +- ...ity_of_biomass_expressed_as_carbon_accumulated_in_roots.json | 2 +- ...ity_of_biomass_expressed_as_carbon_accumulated_in_stems.json | 2 +- ...vity_of_biomass_expressed_as_carbon_accumulated_in_wood.json | 2 +- ...te_of_absorption_of_longwave_energy_in_atmosphere_layer.json | 2 +- ...e_of_absorption_of_shortwave_energy_in_atmosphere_layer.json | 2 +- ...t_rate_of_absorption_of_shortwave_energy_in_ocean_layer.json | 2 +- .../standard_name/net_upward_longwave_flux_in_air.json | 2 +- .../net_upward_longwave_flux_in_air_assuming_clear_sky.json | 2 +- .../standard_name/net_upward_shortwave_flux_in_air.json | 2 +- .../net_upward_shortwave_flux_in_air_assuming_clear_sky.json | 2 +- .../standard_name/nfdrs_1000_hour_fuel_moisture.json | 2 +- .../standard_name/nfdrs_100_hour_fuel_moisture.json | 2 +- data_descriptors/standard_name/nfdrs_10_hour_fuel_moisture.json | 2 +- data_descriptors/standard_name/nfdrs_1_hour_fuel_moisture.json | 2 +- data_descriptors/standard_name/nfdrs_burning_index.json | 2 +- .../standard_name/nfdrs_energy_release_component.json | 2 +- .../standard_name/nfdrs_severe_fire_danger_index.json | 2 +- .../nitrogen_growth_limitation_of_calcareous_phytoplankton.json | 2 +- .../standard_name/nitrogen_growth_limitation_of_diatoms.json | 2 +- ...itrogen_growth_limitation_of_diazotrophic_phytoplankton.json | 2 +- ...trogen_growth_limitation_of_miscellaneous_phytoplankton.json | 2 +- .../nitrogen_growth_limitation_of_picophytoplankton.json | 2 +- ...ogen_mass_content_of_forestry_and_agricultural_products.json | 2 +- ...ucts_due_to_anthropogenic_land_use_or_land_cover_change.json | 2 +- .../nitrogen_mass_flux_into_litter_from_vegetation.json | 2 +- .../standard_name/nitrogen_mass_flux_into_soil_from_litter.json | 2 +- ...en_mass_flux_into_soil_from_vegetation_excluding_litter.json | 2 +- .../standard_name/nitrogen_mass_transport_in_river_channel.json | 2 +- .../non_tidal_elevation_of_sea_surface_height.json | 2 +- .../standard_name/normalized_difference_vegetation_index.json | 2 +- .../northward_air_velocity_relative_to_sea_water.json | 2 +- ...sphere_dry_static_energy_transport_across_unit_distance.json | 2 +- .../standard_name/northward_atmosphere_heat_transport.json | 2 +- ...rthward_atmosphere_water_transport_across_unit_distance.json | 2 +- ...d_atmosphere_water_vapor_transport_across_unit_distance.json | 2 +- .../northward_derivative_of_eastward_sea_ice_velocity.json | 2 +- .../standard_name/northward_derivative_of_eastward_wind.json | 2 +- .../standard_name/northward_derivative_of_northward_wind.json | 2 +- .../northward_derivative_of_wind_from_direction.json | 2 +- .../standard_name/northward_eliassen_palm_flux_in_air.json | 2 +- .../standard_name/northward_flood_water_velocity.json | 2 +- .../northward_friction_velocity_at_sea_water_surface.json | 2 +- .../standard_name/northward_friction_velocity_in_air.json | 2 +- .../northward_heat_flux_in_air_due_to_eddy_advection.json | 2 +- data_descriptors/standard_name/northward_land_ice_velocity.json | 2 +- data_descriptors/standard_name/northward_mass_flux_of_air.json | 2 +- .../standard_name/northward_momentum_flux_correction.json | 2 +- .../northward_northward_derivative_of_geopotential.json | 2 +- .../standard_name/northward_ocean_freshwater_transport.json | 2 +- .../northward_ocean_freshwater_transport_due_to_diffusion.json | 2 +- .../northward_ocean_freshwater_transport_due_to_gyre.json | 2 +- ...northward_ocean_freshwater_transport_due_to_overturning.json | 2 +- ...reshwater_transport_due_to_parameterized_eddy_advection.json | 2 +- .../standard_name/northward_ocean_heat_transport.json | 2 +- .../northward_ocean_heat_transport_due_to_diffusion.json | 2 +- .../northward_ocean_heat_transport_due_to_gyre.json | 2 +- .../northward_ocean_heat_transport_due_to_overturning.json | 2 +- ...cean_heat_transport_due_to_parameterized_eddy_advection.json | 2 +- ...transport_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- ...transport_due_to_parameterized_mesoscale_eddy_diffusion.json | 2 +- ...nsport_due_to_parameterized_submesoscale_eddy_advection.json | 2 +- .../standard_name/northward_ocean_salt_transport.json | 2 +- .../northward_ocean_salt_transport_due_to_diffusion.json | 2 +- .../northward_ocean_salt_transport_due_to_gyre.json | 2 +- .../northward_ocean_salt_transport_due_to_overturning.json | 2 +- ...cean_salt_transport_due_to_parameterized_eddy_advection.json | 2 +- .../standard_name/northward_sea_ice_displacement.json | 2 +- data_descriptors/standard_name/northward_sea_ice_velocity.json | 2 +- .../standard_name/northward_sea_water_velocity.json | 2 +- .../northward_sea_water_velocity_assuming_no_tide.json | 2 +- .../northward_sea_water_velocity_at_sea_floor.json | 2 +- .../northward_sea_water_velocity_due_to_ekman_drift.json | 2 +- ...ea_water_velocity_due_to_parameterized_mesoscale_eddies.json | 2 +- .../northward_sea_water_velocity_due_to_tides.json | 2 +- .../northward_transformed_eulerian_mean_air_velocity.json | 2 +- .../northward_upward_derivative_of_geopotential.json | 2 +- .../standard_name/northward_water_vapor_flux_in_air.json | 2 +- ...apor_transport_across_unit_distance_in_atmosphere_layer.json | 2 +- .../northward_westward_derivative_of_geopotential.json | 2 +- data_descriptors/standard_name/northward_wind.json | 2 +- .../nudging_increment_in_mass_content_of_water_in_soil.json | 2 +- .../nudging_increment_in_snow_and_ice_amount_on_land.json | 2 +- ...number_concentration_of_aerosol_particles_at_stp_in_air.json | 2 +- .../number_concentration_of_aerosol_particles_in_air.json | 2 +- ...umber_concentration_of_ambient_aerosol_particles_in_air.json | 2 +- .../number_concentration_of_biological_taxon_in_sea_water.json | 2 +- ..._concentration_of_biological_taxon_pollen_grains_in_air.json | 2 +- ...oncentration_of_cloud_condensation_nuclei_at_stp_in_air.json | 2 +- ...umber_concentration_of_cloud_condensation_nuclei_in_air.json | 2 +- ...er_concentration_of_cloud_liquid_water_particles_in_air.json | 2 +- ...liquid_water_particles_in_air_at_liquid_water_cloud_top.json | 2 +- ...tration_of_coarse_mode_ambient_aerosol_particles_in_air.json | 2 +- ...id_water_particles_at_convective_liquid_water_cloud_top.json | 2 +- .../number_concentration_of_ice_crystals_in_air.json | 2 +- ...r_concentration_of_ice_crystals_in_air_at_ice_cloud_top.json | 2 +- ...ion_of_nucleation_mode_ambient_aerosol_particles_in_air.json | 2 +- .../number_concentration_of_ozone_molecules_in_air.json | 2 +- .../number_concentration_of_pm10_aerosol_particles_in_air.json | 2 +- .../number_concentration_of_pm2p5_aerosol_particles_in_air.json | 2 +- ...id_water_particles_at_stratiform_liquid_water_cloud_top.json | 2 +- .../number_of_days_with_air_temperature_above_threshold.json | 2 +- .../number_of_days_with_air_temperature_below_threshold.json | 2 +- ...h_lwe_thickness_of_precipitation_amount_above_threshold.json | 2 +- ...number_of_days_with_surface_temperature_below_threshold.json | 2 +- .../number_of_days_with_wind_speed_above_threshold.json | 2 +- .../standard_name/number_of_icebergs_per_unit_area.json | 2 +- .../standard_name/number_of_missing_observations.json | 2 +- data_descriptors/standard_name/number_of_observations.json | 2 +- ...er_size_distribution_of_aerosol_particles_at_stp_in_air.json | 2 +- .../number_size_distribution_of_aerosol_particles_in_air.json | 2 +- ...distribution_of_cloud_condensation_nuclei_at_stp_in_air.json | 2 +- ...r_size_distribution_of_cloud_condensation_nuclei_in_air.json | 2 +- .../standard_name/ocean_barotropic_mass_streamfunction.json | 2 +- .../standard_name/ocean_barotropic_streamfunction.json | 2 +- .../standard_name/ocean_double_sigma_coordinate.json | 2 +- data_descriptors/standard_name/ocean_dynamic_sea_level.json | 2 +- data_descriptors/standard_name/ocean_heat_x_transport.json | 2 +- .../standard_name/ocean_heat_x_transport_due_to_diffusion.json | 2 +- ...an_heat_x_transport_due_to_parameterized_eddy_advection.json | 2 +- data_descriptors/standard_name/ocean_heat_y_transport.json | 2 +- .../standard_name/ocean_heat_y_transport_due_to_diffusion.json | 2 +- ...an_heat_y_transport_due_to_parameterized_eddy_advection.json | 2 +- .../ocean_isopycnal_layer_thickness_diffusivity.json | 2 +- ...ergy_dissipation_per_unit_area_due_to_vertical_friction.json | 2 +- ...tic_energy_dissipation_per_unit_area_due_to_xy_friction.json | 2 +- .../ocean_mass_content_of_dissolved_inorganic_carbon.json | 2 +- .../ocean_mass_content_of_dissolved_organic_carbon.json | 2 +- ...ntent_of_particulate_organic_matter_expressed_as_carbon.json | 2 +- data_descriptors/standard_name/ocean_mass_x_transport.json | 2 +- .../standard_name/ocean_mass_x_transport_due_to_advection.json | 2 +- ...sport_due_to_advection_and_parameterized_eddy_advection.json | 2 +- data_descriptors/standard_name/ocean_mass_y_transport.json | 2 +- .../standard_name/ocean_mass_y_transport_due_to_advection.json | 2 +- ...sport_due_to_advection_and_parameterized_eddy_advection.json | 2 +- .../ocean_meridional_overturning_mass_streamfunction.json | 2 +- ...mass_streamfunction_due_to_parameterized_eddy_advection.json | 2 +- ...mfunction_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- ...nction_due_to_parameterized_submesoscale_eddy_advection.json | 2 +- .../ocean_meridional_overturning_streamfunction.json | 2 +- data_descriptors/standard_name/ocean_mixed_layer_thickness.json | 2 +- .../ocean_mixed_layer_thickness_defined_by_mixing_scheme.json | 2 +- .../ocean_mixed_layer_thickness_defined_by_sigma_t.json | 2 +- .../ocean_mixed_layer_thickness_defined_by_sigma_theta.json | 2 +- .../ocean_mixed_layer_thickness_defined_by_temperature.json | 2 +- ...hickness_defined_by_vertical_tracer_diffusivity_deficit.json | 2 +- ...ckness_defined_by_vertical_tracer_diffusivity_threshold.json | 2 +- .../standard_name/ocean_momentum_xy_biharmonic_diffusivity.json | 2 +- .../standard_name/ocean_momentum_xy_laplacian_diffusivity.json | 2 +- data_descriptors/standard_name/ocean_montgomery_potential.json | 2 +- data_descriptors/standard_name/ocean_obukhov_length.json | 2 +- data_descriptors/standard_name/ocean_relative_vorticity.json | 2 +- data_descriptors/standard_name/ocean_rigid_lid_pressure.json | 2 +- ...id_pressure_expressed_as_sea_surface_height_above_geoid.json | 2 +- data_descriptors/standard_name/ocean_s_coordinate.json | 2 +- data_descriptors/standard_name/ocean_s_coordinate_g1.json | 2 +- data_descriptors/standard_name/ocean_s_coordinate_g2.json | 2 +- data_descriptors/standard_name/ocean_salt_x_transport.json | 2 +- data_descriptors/standard_name/ocean_salt_y_transport.json | 2 +- data_descriptors/standard_name/ocean_sigma_coordinate.json | 2 +- data_descriptors/standard_name/ocean_sigma_z_coordinate.json | 2 +- ...ffusivity_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- ...ffusivity_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- .../ocean_tracer_epineutral_biharmonic_diffusivity.json | 2 +- .../ocean_tracer_epineutral_laplacian_diffusivity.json | 2 +- ...ffusivity_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- .../standard_name/ocean_tracer_xy_biharmonic_diffusivity.json | 2 +- .../standard_name/ocean_tracer_xy_laplacian_diffusivity.json | 2 +- data_descriptors/standard_name/ocean_vertical_diffusivity.json | 2 +- .../standard_name/ocean_vertical_heat_diffusivity.json | 2 +- .../standard_name/ocean_vertical_momentum_diffusivity.json | 2 +- .../ocean_vertical_momentum_diffusivity_due_to_background.json | 2 +- .../ocean_vertical_momentum_diffusivity_due_to_convection.json | 2 +- .../ocean_vertical_momentum_diffusivity_due_to_form_drag.json | 2 +- .../ocean_vertical_momentum_diffusivity_due_to_tides.json | 2 +- .../standard_name/ocean_vertical_salt_diffusivity.json | 2 +- .../standard_name/ocean_vertical_tracer_diffusivity.json | 2 +- .../ocean_vertical_tracer_diffusivity_due_to_background.json | 2 +- .../ocean_vertical_tracer_diffusivity_due_to_convection.json | 2 +- .../ocean_vertical_tracer_diffusivity_due_to_tides.json | 2 +- .../ocean_vertical_tracer_diffusivity_due_to_wind_mixing.json | 2 +- data_descriptors/standard_name/ocean_volume.json | 2 +- .../standard_name/ocean_volume_transport_across_line.json | 2 +- data_descriptors/standard_name/ocean_volume_x_transport.json | 2 +- data_descriptors/standard_name/ocean_volume_y_transport.json | 2 +- .../standard_name/ocean_y_overturning_mass_streamfunction.json | 2 +- ...mass_streamfunction_due_to_parameterized_eddy_advection.json | 2 +- ...mfunction_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- ...nction_due_to_parameterized_submesoscale_eddy_advection.json | 2 +- ...tional_photosynthetic_spherical_irradiance_in_sea_water.json | 2 +- ...l_spherical_irradiance_per_unit_wavelength_in_sea_water.json | 2 +- ...ss_of_atmosphere_layer_due_to_ambient_aerosol_particles.json | 2 +- .../standard_name/original_air_pressure_of_lifted_parcel.json | 2 +- .../outgoing_water_volume_transport_along_river_channel.json | 2 +- .../partial_pressure_of_carbon_dioxide_in_sea_water.json | 2 +- .../standard_name/partial_pressure_of_methane_in_sea_water.json | 2 +- data_descriptors/standard_name/perceived_temperature.json | 2 +- .../standard_name/permafrost_active_layer_thickness.json | 2 +- data_descriptors/standard_name/permafrost_area_fraction.json | 2 +- data_descriptors/standard_name/permafrost_layer_thickness.json | 2 +- .../standard_name/phase_of_global_average_sea_level_change.json | 2 +- .../phosphorus_mass_transport_in_river_channel.json | 2 +- .../standard_name/photolysis_rate_of_molecular_oxygen.json | 2 +- .../standard_name/photolysis_rate_of_nitrogen_dioxide.json | 2 +- data_descriptors/standard_name/photolysis_rate_of_ozone.json | 2 +- .../photolysis_rate_of_ozone_to_1D_oxygen_atom.json | 2 +- .../standard_name/physiological_equivalent_temperature.json | 2 +- data_descriptors/standard_name/planetary_albedo.json | 2 +- data_descriptors/standard_name/platform_azimuth_angle.json | 2 +- data_descriptors/standard_name/platform_course.json | 2 +- data_descriptors/standard_name/platform_heave.json | 2 +- data_descriptors/standard_name/platform_heave_down.json | 2 +- data_descriptors/standard_name/platform_heave_rate.json | 2 +- data_descriptors/standard_name/platform_heave_rate_down.json | 2 +- data_descriptors/standard_name/platform_heave_rate_up.json | 2 +- data_descriptors/standard_name/platform_heave_up.json | 2 +- data_descriptors/standard_name/platform_id.json | 2 +- data_descriptors/standard_name/platform_name.json | 2 +- data_descriptors/standard_name/platform_orientation.json | 2 +- data_descriptors/standard_name/platform_pitch.json | 2 +- data_descriptors/standard_name/platform_pitch_fore_down.json | 2 +- data_descriptors/standard_name/platform_pitch_fore_up.json | 2 +- data_descriptors/standard_name/platform_pitch_rate.json | 2 +- .../standard_name/platform_pitch_rate_fore_down.json | 2 +- data_descriptors/standard_name/platform_pitch_rate_fore_up.json | 2 +- data_descriptors/standard_name/platform_roll.json | 2 +- data_descriptors/standard_name/platform_roll_rate.json | 2 +- .../standard_name/platform_roll_rate_starboard_down.json | 2 +- .../standard_name/platform_roll_rate_starboard_up.json | 2 +- .../standard_name/platform_roll_starboard_down.json | 2 +- data_descriptors/standard_name/platform_roll_starboard_up.json | 2 +- data_descriptors/standard_name/platform_speed_wrt_air.json | 2 +- data_descriptors/standard_name/platform_speed_wrt_ground.json | 2 +- .../standard_name/platform_speed_wrt_sea_water.json | 2 +- data_descriptors/standard_name/platform_surge.json | 2 +- data_descriptors/standard_name/platform_surge_aft.json | 2 +- data_descriptors/standard_name/platform_surge_fore.json | 2 +- data_descriptors/standard_name/platform_surge_rate.json | 2 +- data_descriptors/standard_name/platform_surge_rate_aft.json | 2 +- data_descriptors/standard_name/platform_surge_rate_fore.json | 2 +- data_descriptors/standard_name/platform_sway.json | 2 +- data_descriptors/standard_name/platform_sway_port.json | 2 +- data_descriptors/standard_name/platform_sway_rate.json | 2 +- data_descriptors/standard_name/platform_sway_rate_port.json | 2 +- .../standard_name/platform_sway_rate_starboard.json | 2 +- data_descriptors/standard_name/platform_sway_starboard.json | 2 +- data_descriptors/standard_name/platform_view_angle.json | 2 +- data_descriptors/standard_name/platform_yaw.json | 2 +- data_descriptors/standard_name/platform_yaw_fore_port.json | 2 +- data_descriptors/standard_name/platform_yaw_fore_starboard.json | 2 +- data_descriptors/standard_name/platform_yaw_rate.json | 2 +- data_descriptors/standard_name/platform_yaw_rate_fore_port.json | 2 +- .../standard_name/platform_yaw_rate_fore_starboard.json | 2 +- data_descriptors/standard_name/platform_zenith_angle.json | 2 +- .../potential_energy_content_of_atmosphere_layer.json | 2 +- .../standard_name/potential_vorticity_of_atmosphere_layer.json | 2 +- .../standard_name/potential_vorticity_of_ocean_layer.json | 2 +- data_descriptors/standard_name/precipitation_amount.json | 2 +- data_descriptors/standard_name/precipitation_flux.json | 2 +- .../standard_name/precipitation_flux_containing_17O.json | 2 +- .../standard_name/precipitation_flux_containing_18O.json | 2 +- .../standard_name/precipitation_flux_containing_single_2H.json | 2 +- .../standard_name/precipitation_flux_onto_canopy.json | 2 +- .../predominant_precipitation_type_at_surface.json | 2 +- ...re_at_effective_cloud_top_defined_by_infrared_radiation.json | 2 +- ...obability_distribution_of_wind_from_direction_over_time.json | 2 +- .../product_of_air_temperature_and_specific_humidity.json | 2 +- .../product_of_eastward_sea_water_velocity_and_salinity.json | 2 +- .../product_of_eastward_sea_water_velocity_and_temperature.json | 2 +- .../product_of_eastward_wind_and_air_temperature.json | 2 +- .../product_of_eastward_wind_and_geopotential_height.json | 2 +- ...f_eastward_wind_and_lagrangian_tendency_of_air_pressure.json | 2 +- .../product_of_eastward_wind_and_northward_wind.json | 2 +- .../product_of_eastward_wind_and_specific_humidity.json | 2 +- .../product_of_eastward_wind_and_upward_air_velocity.json | 2 +- ...lagrangian_tendency_of_air_pressure_and_air_temperature.json | 2 +- ...angian_tendency_of_air_pressure_and_geopotential_height.json | 2 +- ...grangian_tendency_of_air_pressure_and_specific_humidity.json | 2 +- .../product_of_northward_sea_water_velocity_and_salinity.json | 2 +- ...product_of_northward_sea_water_velocity_and_temperature.json | 2 +- .../product_of_northward_wind_and_air_temperature.json | 2 +- .../product_of_northward_wind_and_geopotential_height.json | 2 +- ..._northward_wind_and_lagrangian_tendency_of_air_pressure.json | 2 +- .../product_of_northward_wind_and_specific_humidity.json | 2 +- .../product_of_northward_wind_and_upward_air_velocity.json | 2 +- .../product_of_upward_air_velocity_and_air_temperature.json | 2 +- .../product_of_upward_air_velocity_and_specific_humidity.json | 2 +- ...of_wind_speed_and_water_vapor_saturation_deficit_in_air.json | 2 +- .../standard_name/projection_x_angular_coordinate.json | 2 +- data_descriptors/standard_name/projection_x_coordinate.json | 2 +- .../standard_name/projection_y_angular_coordinate.json | 2 +- data_descriptors/standard_name/projection_y_coordinate.json | 2 +- ...le_signal_returns_from_acoustic_instrument_in_sea_water.json | 2 +- data_descriptors/standard_name/quality_flag.json | 2 +- .../radial_sea_water_velocity_away_from_instrument.json | 2 +- .../radial_sea_water_velocity_toward_instrument.json | 2 +- .../radial_velocity_of_scatterers_away_from_instrument.json | 2 +- .../radial_velocity_of_scatterers_toward_instrument.json | 2 +- data_descriptors/standard_name/radiation_frequency.json | 2 +- data_descriptors/standard_name/radiation_wavelength.json | 2 +- .../radio_signal_roundtrip_travel_time_in_air.json | 2 +- .../standard_name/radioactivity_concentration_in_air.json | 2 +- .../radioactivity_concentration_of_101Mo_in_air.json | 2 +- .../radioactivity_concentration_of_101Tc_in_air.json | 2 +- .../radioactivity_concentration_of_102Mo_in_air.json | 2 +- .../radioactivity_concentration_of_102Tc_in_air.json | 2 +- .../radioactivity_concentration_of_102mTc_in_air.json | 2 +- .../radioactivity_concentration_of_103Ru_in_air.json | 2 +- .../radioactivity_concentration_of_103mRh_in_air.json | 2 +- .../radioactivity_concentration_of_104Tc_in_air.json | 2 +- .../radioactivity_concentration_of_105Rh_in_air.json | 2 +- .../radioactivity_concentration_of_105Ru_in_air.json | 2 +- .../radioactivity_concentration_of_105mRh_in_air.json | 2 +- .../radioactivity_concentration_of_106Rh_in_air.json | 2 +- .../radioactivity_concentration_of_106Ru_in_air.json | 2 +- .../radioactivity_concentration_of_106mRh_in_air.json | 2 +- .../radioactivity_concentration_of_107Pd_in_air.json | 2 +- .../radioactivity_concentration_of_107Rh_in_air.json | 2 +- .../radioactivity_concentration_of_107mPd_in_air.json | 2 +- .../radioactivity_concentration_of_109Pd_in_air.json | 2 +- .../radioactivity_concentration_of_109mAg_in_air.json | 2 +- .../radioactivity_concentration_of_110mAg_in_air.json | 2 +- .../radioactivity_concentration_of_111Ag_in_air.json | 2 +- .../radioactivity_concentration_of_111Pd_in_air.json | 2 +- .../radioactivity_concentration_of_111mAg_in_air.json | 2 +- .../radioactivity_concentration_of_111mCd_in_air.json | 2 +- .../radioactivity_concentration_of_111mPd_in_air.json | 2 +- .../radioactivity_concentration_of_112Ag_in_air.json | 2 +- .../radioactivity_concentration_of_112Pd_in_air.json | 2 +- .../radioactivity_concentration_of_113Ag_in_air.json | 2 +- .../radioactivity_concentration_of_113Cd_in_air.json | 2 +- .../radioactivity_concentration_of_113mAg_in_air.json | 2 +- .../radioactivity_concentration_of_113mCd_in_air.json | 2 +- .../radioactivity_concentration_of_113mIn_in_air.json | 2 +- .../radioactivity_concentration_of_115Ag_in_air.json | 2 +- .../radioactivity_concentration_of_115Cd_in_air.json | 2 +- .../radioactivity_concentration_of_115In_in_air.json | 2 +- .../radioactivity_concentration_of_115mAg_in_air.json | 2 +- .../radioactivity_concentration_of_115mCd_in_air.json | 2 +- .../radioactivity_concentration_of_115mIn_in_air.json | 2 +- .../radioactivity_concentration_of_116In_in_air.json | 2 +- .../radioactivity_concentration_of_116mIn_in_air.json | 2 +- .../radioactivity_concentration_of_117Cd_in_air.json | 2 +- .../radioactivity_concentration_of_117In_in_air.json | 2 +- .../radioactivity_concentration_of_117mCd_in_air.json | 2 +- .../radioactivity_concentration_of_117mIn_in_air.json | 2 +- .../radioactivity_concentration_of_117mSn_in_air.json | 2 +- .../radioactivity_concentration_of_118Cd_in_air.json | 2 +- .../radioactivity_concentration_of_118In_in_air.json | 2 +- .../radioactivity_concentration_of_118mIn_in_air.json | 2 +- .../radioactivity_concentration_of_119In_in_air.json | 2 +- .../radioactivity_concentration_of_119mIn_in_air.json | 2 +- .../radioactivity_concentration_of_119mSn_in_air.json | 2 +- .../radioactivity_concentration_of_11C_in_air.json | 2 +- .../radioactivity_concentration_of_121Sn_in_air.json | 2 +- .../radioactivity_concentration_of_121mSn_in_air.json | 2 +- .../radioactivity_concentration_of_123Sn_in_air.json | 2 +- .../radioactivity_concentration_of_123mSn_in_air.json | 2 +- .../radioactivity_concentration_of_124Sb_in_air.json | 2 +- .../radioactivity_concentration_of_124mSb_in_air.json | 2 +- .../radioactivity_concentration_of_125Sb_in_air.json | 2 +- .../radioactivity_concentration_of_125Sn_in_air.json | 2 +- .../radioactivity_concentration_of_125mTe_in_air.json | 2 +- .../radioactivity_concentration_of_126Sb_in_air.json | 2 +- .../radioactivity_concentration_of_126Sn_in_air.json | 2 +- .../radioactivity_concentration_of_126mSb_in_air.json | 2 +- .../radioactivity_concentration_of_127Sb_in_air.json | 2 +- .../radioactivity_concentration_of_127Sn_in_air.json | 2 +- .../radioactivity_concentration_of_127Te_in_air.json | 2 +- .../radioactivity_concentration_of_127mTe_in_air.json | 2 +- .../radioactivity_concentration_of_128Sb_in_air.json | 2 +- .../radioactivity_concentration_of_128Sn_in_air.json | 2 +- .../radioactivity_concentration_of_128mSb_in_air.json | 2 +- .../radioactivity_concentration_of_129I_in_air.json | 2 +- .../radioactivity_concentration_of_129Sb_in_air.json | 2 +- .../radioactivity_concentration_of_129Te_in_air.json | 2 +- .../radioactivity_concentration_of_129mTe_in_air.json | 2 +- .../radioactivity_concentration_of_129mXe_in_air.json | 2 +- .../radioactivity_concentration_of_130I_in_air.json | 2 +- .../radioactivity_concentration_of_130Sb_in_air.json | 2 +- .../radioactivity_concentration_of_130Sn_in_air.json | 2 +- .../radioactivity_concentration_of_130mI_in_air.json | 2 +- .../radioactivity_concentration_of_130mSb_in_air.json | 2 +- .../radioactivity_concentration_of_131I_in_air.json | 2 +- .../radioactivity_concentration_of_131Sb_in_air.json | 2 +- .../radioactivity_concentration_of_131Te_in_air.json | 2 +- .../radioactivity_concentration_of_131mTe_in_air.json | 2 +- .../radioactivity_concentration_of_131mXe_in_air.json | 2 +- .../radioactivity_concentration_of_132I_in_air.json | 2 +- .../radioactivity_concentration_of_132Te_in_air.json | 2 +- .../radioactivity_concentration_of_133I_in_air.json | 2 +- .../radioactivity_concentration_of_133Te_in_air.json | 2 +- .../radioactivity_concentration_of_133Xe_in_air.json | 2 +- .../radioactivity_concentration_of_133mI_in_air.json | 2 +- .../radioactivity_concentration_of_133mTe_in_air.json | 2 +- .../radioactivity_concentration_of_133mXe_in_air.json | 2 +- .../radioactivity_concentration_of_134Cs_in_air.json | 2 +- .../radioactivity_concentration_of_134I_in_air.json | 2 +- .../radioactivity_concentration_of_134Te_in_air.json | 2 +- .../radioactivity_concentration_of_134mCs_in_air.json | 2 +- .../radioactivity_concentration_of_134mI_in_air.json | 2 +- .../radioactivity_concentration_of_134mXe_in_air.json | 2 +- .../radioactivity_concentration_of_135Cs_in_air.json | 2 +- .../radioactivity_concentration_of_135I_in_air.json | 2 +- .../radioactivity_concentration_of_135Xe_in_air.json | 2 +- .../radioactivity_concentration_of_135mBa_in_air.json | 2 +- .../radioactivity_concentration_of_135mCs_in_air.json | 2 +- .../radioactivity_concentration_of_135mXe_in_air.json | 2 +- .../radioactivity_concentration_of_136Cs_in_air.json | 2 +- .../radioactivity_concentration_of_137Cs_in_air.json | 2 +- .../radioactivity_concentration_of_137Xe_in_air.json | 2 +- .../radioactivity_concentration_of_137mBa_in_air.json | 2 +- .../radioactivity_concentration_of_138Cs_in_air.json | 2 +- .../radioactivity_concentration_of_138Xe_in_air.json | 2 +- .../radioactivity_concentration_of_139Ba_in_air.json | 2 +- .../radioactivity_concentration_of_13N_in_air.json | 2 +- .../radioactivity_concentration_of_140Ba_in_air.json | 2 +- .../radioactivity_concentration_of_140La_in_air.json | 2 +- .../radioactivity_concentration_of_141Ce_in_air.json | 2 +- .../radioactivity_concentration_of_141La_in_air.json | 2 +- .../radioactivity_concentration_of_142Ce_in_air.json | 2 +- .../radioactivity_concentration_of_142La_in_air.json | 2 +- .../radioactivity_concentration_of_142Pr_in_air.json | 2 +- .../radioactivity_concentration_of_142mPr_in_air.json | 2 +- .../radioactivity_concentration_of_143Ce_in_air.json | 2 +- .../radioactivity_concentration_of_143La_in_air.json | 2 +- .../radioactivity_concentration_of_143Pr_in_air.json | 2 +- .../radioactivity_concentration_of_144Ce_in_air.json | 2 +- .../radioactivity_concentration_of_144Nd_in_air.json | 2 +- .../radioactivity_concentration_of_144Pr_in_air.json | 2 +- .../radioactivity_concentration_of_144mPr_in_air.json | 2 +- .../radioactivity_concentration_of_145Pr_in_air.json | 2 +- .../radioactivity_concentration_of_146Ce_in_air.json | 2 +- .../radioactivity_concentration_of_146Pr_in_air.json | 2 +- .../radioactivity_concentration_of_147Nd_in_air.json | 2 +- .../radioactivity_concentration_of_147Pm_in_air.json | 2 +- .../radioactivity_concentration_of_147Pr_in_air.json | 2 +- .../radioactivity_concentration_of_147Sm_in_air.json | 2 +- .../radioactivity_concentration_of_148Pm_in_air.json | 2 +- .../radioactivity_concentration_of_148Sm_in_air.json | 2 +- .../radioactivity_concentration_of_148mPm_in_air.json | 2 +- .../radioactivity_concentration_of_149Nd_in_air.json | 2 +- .../radioactivity_concentration_of_149Pm_in_air.json | 2 +- .../radioactivity_concentration_of_149Sm_in_air.json | 2 +- .../radioactivity_concentration_of_150Pm_in_air.json | 2 +- .../radioactivity_concentration_of_151Nd_in_air.json | 2 +- .../radioactivity_concentration_of_151Pm_in_air.json | 2 +- .../radioactivity_concentration_of_151Sm_in_air.json | 2 +- .../radioactivity_concentration_of_152Nd_in_air.json | 2 +- .../radioactivity_concentration_of_152Pm_in_air.json | 2 +- .../radioactivity_concentration_of_152mPm_in_air.json | 2 +- .../radioactivity_concentration_of_153Sm_in_air.json | 2 +- .../radioactivity_concentration_of_154Eu_in_air.json | 2 +- .../radioactivity_concentration_of_155Eu_in_air.json | 2 +- .../radioactivity_concentration_of_155Sm_in_air.json | 2 +- .../radioactivity_concentration_of_156Eu_in_air.json | 2 +- .../radioactivity_concentration_of_156Sm_in_air.json | 2 +- .../radioactivity_concentration_of_157Eu_in_air.json | 2 +- .../radioactivity_concentration_of_158Eu_in_air.json | 2 +- .../radioactivity_concentration_of_159Eu_in_air.json | 2 +- .../radioactivity_concentration_of_159Gd_in_air.json | 2 +- .../radioactivity_concentration_of_15O_in_air.json | 2 +- .../radioactivity_concentration_of_160Tb_in_air.json | 2 +- .../radioactivity_concentration_of_161Tb_in_air.json | 2 +- .../radioactivity_concentration_of_162Gd_in_air.json | 2 +- .../radioactivity_concentration_of_162Tb_in_air.json | 2 +- .../radioactivity_concentration_of_162mTb_in_air.json | 2 +- .../radioactivity_concentration_of_163Tb_in_air.json | 2 +- .../radioactivity_concentration_of_165Dy_in_air.json | 2 +- .../radioactivity_concentration_of_18F_in_air.json | 2 +- .../radioactivity_concentration_of_206Hg_in_air.json | 2 +- .../radioactivity_concentration_of_206Tl_in_air.json | 2 +- .../radioactivity_concentration_of_207Tl_in_air.json | 2 +- .../radioactivity_concentration_of_207mPb_in_air.json | 2 +- .../radioactivity_concentration_of_208Tl_in_air.json | 2 +- .../radioactivity_concentration_of_209Bi_in_air.json | 2 +- .../radioactivity_concentration_of_209Pb_in_air.json | 2 +- .../radioactivity_concentration_of_209Tl_in_air.json | 2 +- .../radioactivity_concentration_of_210Bi_in_air.json | 2 +- .../radioactivity_concentration_of_210Pb_in_air.json | 2 +- .../radioactivity_concentration_of_210Po_in_air.json | 2 +- .../radioactivity_concentration_of_210Tl_in_air.json | 2 +- .../radioactivity_concentration_of_211Bi_in_air.json | 2 +- .../radioactivity_concentration_of_211Pb_in_air.json | 2 +- .../radioactivity_concentration_of_211Po_in_air.json | 2 +- .../radioactivity_concentration_of_212Bi_in_air.json | 2 +- .../radioactivity_concentration_of_212Pb_in_air.json | 2 +- .../radioactivity_concentration_of_212Po_in_air.json | 2 +- .../radioactivity_concentration_of_213Bi_in_air.json | 2 +- .../radioactivity_concentration_of_213Pb_in_air.json | 2 +- .../radioactivity_concentration_of_213Po_in_air.json | 2 +- .../radioactivity_concentration_of_214Bi_in_air.json | 2 +- .../radioactivity_concentration_of_214Pb_in_air.json | 2 +- .../radioactivity_concentration_of_214Po_in_air.json | 2 +- .../radioactivity_concentration_of_215At_in_air.json | 2 +- .../radioactivity_concentration_of_215Bi_in_air.json | 2 +- .../radioactivity_concentration_of_215Po_in_air.json | 2 +- .../radioactivity_concentration_of_216At_in_air.json | 2 +- .../radioactivity_concentration_of_216Po_in_air.json | 2 +- .../radioactivity_concentration_of_217At_in_air.json | 2 +- .../radioactivity_concentration_of_217Po_in_air.json | 2 +- .../radioactivity_concentration_of_218At_in_air.json | 2 +- .../radioactivity_concentration_of_218Po_in_air.json | 2 +- .../radioactivity_concentration_of_218Rn_in_air.json | 2 +- .../radioactivity_concentration_of_219At_in_air.json | 2 +- .../radioactivity_concentration_of_219Rn_in_air.json | 2 +- .../radioactivity_concentration_of_220Rn_in_air.json | 2 +- .../radioactivity_concentration_of_221Fr_in_air.json | 2 +- .../radioactivity_concentration_of_221Rn_in_air.json | 2 +- .../radioactivity_concentration_of_222Fr_in_air.json | 2 +- .../radioactivity_concentration_of_222Ra_in_air.json | 2 +- .../radioactivity_concentration_of_222Rn_in_air.json | 2 +- .../radioactivity_concentration_of_223Fr_in_air.json | 2 +- .../radioactivity_concentration_of_223Ra_in_air.json | 2 +- .../radioactivity_concentration_of_223Rn_in_air.json | 2 +- .../radioactivity_concentration_of_224Ra_in_air.json | 2 +- .../radioactivity_concentration_of_225Ac_in_air.json | 2 +- .../radioactivity_concentration_of_225Ra_in_air.json | 2 +- .../radioactivity_concentration_of_226Ac_in_air.json | 2 +- .../radioactivity_concentration_of_226Ra_in_air.json | 2 +- .../radioactivity_concentration_of_226Th_in_air.json | 2 +- .../radioactivity_concentration_of_227Ac_in_air.json | 2 +- .../radioactivity_concentration_of_227Ra_in_air.json | 2 +- .../radioactivity_concentration_of_227Th_in_air.json | 2 +- .../radioactivity_concentration_of_228Ac_in_air.json | 2 +- .../radioactivity_concentration_of_228Ra_in_air.json | 2 +- .../radioactivity_concentration_of_228Th_in_air.json | 2 +- .../radioactivity_concentration_of_229Ac_in_air.json | 2 +- .../radioactivity_concentration_of_229Ra_in_air.json | 2 +- .../radioactivity_concentration_of_229Th_in_air.json | 2 +- .../radioactivity_concentration_of_230Pa_in_air.json | 2 +- .../radioactivity_concentration_of_230Th_in_air.json | 2 +- .../radioactivity_concentration_of_230U_in_air.json | 2 +- .../radioactivity_concentration_of_231Pa_in_air.json | 2 +- .../radioactivity_concentration_of_231Th_in_air.json | 2 +- .../radioactivity_concentration_of_231U_in_air.json | 2 +- .../radioactivity_concentration_of_232Pa_in_air.json | 2 +- .../radioactivity_concentration_of_232Th_in_air.json | 2 +- .../radioactivity_concentration_of_232U_in_air.json | 2 +- .../radioactivity_concentration_of_233Pa_in_air.json | 2 +- .../radioactivity_concentration_of_233Th_in_air.json | 2 +- .../radioactivity_concentration_of_233U_in_air.json | 2 +- .../radioactivity_concentration_of_234Pa_in_air.json | 2 +- .../radioactivity_concentration_of_234Th_in_air.json | 2 +- .../radioactivity_concentration_of_234U_in_air.json | 2 +- .../radioactivity_concentration_of_234mPa_in_air.json | 2 +- .../radioactivity_concentration_of_235Np_in_air.json | 2 +- .../radioactivity_concentration_of_235Pu_in_air.json | 2 +- .../radioactivity_concentration_of_235U_in_air.json | 2 +- .../radioactivity_concentration_of_236Np_in_air.json | 2 +- .../radioactivity_concentration_of_236Pu_in_air.json | 2 +- .../radioactivity_concentration_of_236U_in_air.json | 2 +- .../radioactivity_concentration_of_236mNp_in_air.json | 2 +- .../radioactivity_concentration_of_237Np_in_air.json | 2 +- .../radioactivity_concentration_of_237Pu_in_air.json | 2 +- .../radioactivity_concentration_of_237U_in_air.json | 2 +- .../radioactivity_concentration_of_238Np_in_air.json | 2 +- .../radioactivity_concentration_of_238Pu_in_air.json | 2 +- .../radioactivity_concentration_of_238U_in_air.json | 2 +- .../radioactivity_concentration_of_239Np_in_air.json | 2 +- .../radioactivity_concentration_of_239Pu_in_air.json | 2 +- .../radioactivity_concentration_of_239U_in_air.json | 2 +- .../radioactivity_concentration_of_240Am_in_air.json | 2 +- .../radioactivity_concentration_of_240Np_in_air.json | 2 +- .../radioactivity_concentration_of_240Pu_in_air.json | 2 +- .../radioactivity_concentration_of_240U_in_air.json | 2 +- .../radioactivity_concentration_of_240mNp_in_air.json | 2 +- .../radioactivity_concentration_of_241Am_in_air.json | 2 +- .../radioactivity_concentration_of_241Cm_in_air.json | 2 +- .../radioactivity_concentration_of_241Pu_in_air.json | 2 +- .../radioactivity_concentration_of_242Am_in_air.json | 2 +- .../radioactivity_concentration_of_242Cm_in_air.json | 2 +- .../radioactivity_concentration_of_242Pu_in_air.json | 2 +- .../radioactivity_concentration_of_242m1Am_in_air.json | 2 +- .../radioactivity_concentration_of_242m2Am_in_air.json | 2 +- .../radioactivity_concentration_of_243Am_in_air.json | 2 +- .../radioactivity_concentration_of_243Cm_in_air.json | 2 +- .../radioactivity_concentration_of_243Pu_in_air.json | 2 +- .../radioactivity_concentration_of_244Am_in_air.json | 2 +- .../radioactivity_concentration_of_244Cm_in_air.json | 2 +- .../radioactivity_concentration_of_244Pu_in_air.json | 2 +- .../radioactivity_concentration_of_244mAm_in_air.json | 2 +- .../radioactivity_concentration_of_245Am_in_air.json | 2 +- .../radioactivity_concentration_of_245Cm_in_air.json | 2 +- .../radioactivity_concentration_of_245Pu_in_air.json | 2 +- .../radioactivity_concentration_of_246Cm_in_air.json | 2 +- .../radioactivity_concentration_of_247Cm_in_air.json | 2 +- .../radioactivity_concentration_of_248Cm_in_air.json | 2 +- .../radioactivity_concentration_of_249Bk_in_air.json | 2 +- .../radioactivity_concentration_of_249Cf_in_air.json | 2 +- .../radioactivity_concentration_of_249Cm_in_air.json | 2 +- .../radioactivity_concentration_of_24Na_in_air.json | 2 +- .../radioactivity_concentration_of_250Bk_in_air.json | 2 +- .../radioactivity_concentration_of_250Cf_in_air.json | 2 +- .../radioactivity_concentration_of_250Cm_in_air.json | 2 +- .../radioactivity_concentration_of_251Cf_in_air.json | 2 +- .../radioactivity_concentration_of_252Cf_in_air.json | 2 +- .../radioactivity_concentration_of_253Cf_in_air.json | 2 +- .../radioactivity_concentration_of_253Es_in_air.json | 2 +- .../radioactivity_concentration_of_254Cf_in_air.json | 2 +- .../radioactivity_concentration_of_254Es_in_air.json | 2 +- .../radioactivity_concentration_of_254mEs_in_air.json | 2 +- .../radioactivity_concentration_of_255Es_in_air.json | 2 +- .../standard_name/radioactivity_concentration_of_3H_in_air.json | 2 +- .../radioactivity_concentration_of_41Ar_in_air.json | 2 +- .../radioactivity_concentration_of_54Mn_in_air.json | 2 +- .../radioactivity_concentration_of_58Co_in_air.json | 2 +- .../radioactivity_concentration_of_60Co_in_air.json | 2 +- .../radioactivity_concentration_of_72Ga_in_air.json | 2 +- .../radioactivity_concentration_of_72Zn_in_air.json | 2 +- .../radioactivity_concentration_of_73Ga_in_air.json | 2 +- .../radioactivity_concentration_of_75Ge_in_air.json | 2 +- .../radioactivity_concentration_of_77As_in_air.json | 2 +- .../radioactivity_concentration_of_77Ge_in_air.json | 2 +- .../radioactivity_concentration_of_77mGe_in_air.json | 2 +- .../radioactivity_concentration_of_78As_in_air.json | 2 +- .../radioactivity_concentration_of_78Ge_in_air.json | 2 +- .../radioactivity_concentration_of_79Se_in_air.json | 2 +- .../radioactivity_concentration_of_81Se_in_air.json | 2 +- .../radioactivity_concentration_of_81mSe_in_air.json | 2 +- .../radioactivity_concentration_of_82Br_in_air.json | 2 +- .../radioactivity_concentration_of_82mBr_in_air.json | 2 +- .../radioactivity_concentration_of_83Br_in_air.json | 2 +- .../radioactivity_concentration_of_83Se_in_air.json | 2 +- .../radioactivity_concentration_of_83mKr_in_air.json | 2 +- .../radioactivity_concentration_of_83mSe_in_air.json | 2 +- .../radioactivity_concentration_of_84Br_in_air.json | 2 +- .../radioactivity_concentration_of_84mBr_in_air.json | 2 +- .../radioactivity_concentration_of_85Kr_in_air.json | 2 +- .../radioactivity_concentration_of_85mKr_in_air.json | 2 +- .../radioactivity_concentration_of_86Rb_in_air.json | 2 +- .../radioactivity_concentration_of_86mRb_in_air.json | 2 +- .../radioactivity_concentration_of_87Kr_in_air.json | 2 +- .../radioactivity_concentration_of_87Rb_in_air.json | 2 +- .../radioactivity_concentration_of_88Kr_in_air.json | 2 +- .../radioactivity_concentration_of_88Rb_in_air.json | 2 +- .../radioactivity_concentration_of_89Kr_in_air.json | 2 +- .../radioactivity_concentration_of_89Rb_in_air.json | 2 +- .../radioactivity_concentration_of_89Sr_in_air.json | 2 +- .../radioactivity_concentration_of_90Sr_in_air.json | 2 +- .../radioactivity_concentration_of_90Y_in_air.json | 2 +- .../radioactivity_concentration_of_90mY_in_air.json | 2 +- .../radioactivity_concentration_of_91Sr_in_air.json | 2 +- .../radioactivity_concentration_of_91Y_in_air.json | 2 +- .../radioactivity_concentration_of_91mY_in_air.json | 2 +- .../radioactivity_concentration_of_92Sr_in_air.json | 2 +- .../radioactivity_concentration_of_92Y_in_air.json | 2 +- .../radioactivity_concentration_of_93Y_in_air.json | 2 +- .../radioactivity_concentration_of_93Zr_in_air.json | 2 +- .../radioactivity_concentration_of_94Nb_in_air.json | 2 +- .../radioactivity_concentration_of_94Y_in_air.json | 2 +- .../radioactivity_concentration_of_94mNb_in_air.json | 2 +- .../radioactivity_concentration_of_95Nb_in_air.json | 2 +- .../radioactivity_concentration_of_95Y_in_air.json | 2 +- .../radioactivity_concentration_of_95Zr_in_air.json | 2 +- .../radioactivity_concentration_of_95mNb_in_air.json | 2 +- .../radioactivity_concentration_of_96Nb_in_air.json | 2 +- .../radioactivity_concentration_of_97Nb_in_air.json | 2 +- .../radioactivity_concentration_of_97Zr_in_air.json | 2 +- .../radioactivity_concentration_of_97mNb_in_air.json | 2 +- .../radioactivity_concentration_of_98Nb_in_air.json | 2 +- .../radioactivity_concentration_of_99Mo_in_air.json | 2 +- .../radioactivity_concentration_of_99Tc_in_air.json | 2 +- .../radioactivity_concentration_of_99mTc_in_air.json | 2 +- ...adius_of_tropical_cyclone_central_dense_overcast_region.json | 2 +- .../standard_name/radius_of_tropical_cyclone_eye.json | 2 +- ...radius_of_tropical_cyclone_maximum_sustained_wind_speed.json | 2 +- data_descriptors/standard_name/rainfall_amount.json | 2 +- data_descriptors/standard_name/rainfall_flux.json | 2 +- data_descriptors/standard_name/rainfall_rate.json | 2 +- ..._kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json | 2 +- ...ing_averaging_kernel_of_mole_fraction_of_methane_in_air.json | 2 +- .../standard_name/rate_of_change_test_quality_flag.json | 2 +- ...hydroxyl_radical_destruction_due_to_reaction_with_nmvoc.json | 2 +- ...lume_in_frozen_ground_to_pore_volume_in_unfrozen_ground.json | 2 +- ...r_potential_temperature_anomaly_to_relaxation_timescale.json | 2 +- ...ater_practical_salinity_anomaly_to_relaxation_timescale.json | 2 +- ...ging_instrument_in_air_due_to_ambient_aerosol_particles.json | 2 +- ...tive_of_ocean_rigid_lid_pressure_to_sea_surface_density.json | 2 +- ...tive_of_ocean_rigid_lid_pressure_to_sea_surface_density.json | 2 +- data_descriptors/standard_name/realization.json | 2 +- .../received_power_of_radio_wave_in_air_scattered_by_air.json | 2 +- .../received_power_of_radio_wave_scattered_by_air.json | 2 +- ...ference_air_pressure_for_atmosphere_vertical_coordinate.json | 2 +- data_descriptors/standard_name/reference_epoch.json | 2 +- .../reference_mole_fraction_of_methane_in_air.json | 2 +- .../standard_name/reference_mole_fraction_of_ozone_in_air.json | 2 +- data_descriptors/standard_name/reference_pressure.json | 2 +- ...eference_sea_water_density_for_boussinesq_approximation.json | 2 +- data_descriptors/standard_name/region.json | 2 +- data_descriptors/standard_name/relative_humidity.json | 2 +- .../relative_humidity_for_aerosol_particle_size_selection.json | 2 +- .../standard_name/relative_platform_azimuth_angle.json | 2 +- .../standard_name/relative_sensor_azimuth_angle.json | 2 +- ..._kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json | 2 +- ...ing_averaging_kernel_of_mole_fraction_of_methane_in_air.json | 2 +- .../standard_name/richardson_number_in_sea_water.json | 2 +- ..._kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json | 2 +- ...ing_averaging_kernel_of_mole_fraction_of_methane_in_air.json | 2 +- data_descriptors/standard_name/root_depth.json | 2 +- data_descriptors/standard_name/root_mass_content_of_carbon.json | 2 +- .../standard_name/root_mass_content_of_nitrogen.json | 2 +- data_descriptors/standard_name/runoff_amount.json | 2 +- .../standard_name/runoff_amount_excluding_baseflow.json | 2 +- data_descriptors/standard_name/runoff_flux.json | 2 +- .../salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json | 2 +- .../standard_name/salt_flux_into_sea_water_from_rivers.json | 2 +- data_descriptors/standard_name/scattering_angle.json | 2 +- .../scene_type_of_dvorak_tropical_cyclone_cloud_region.json | 2 +- .../scene_type_of_dvorak_tropical_cyclone_eye_region.json | 2 +- data_descriptors/standard_name/sea_area.json | 2 +- data_descriptors/standard_name/sea_area_fraction.json | 2 +- data_descriptors/standard_name/sea_binary_mask.json | 2 +- data_descriptors/standard_name/sea_floor_depth_below_geoid.json | 2 +- .../standard_name/sea_floor_depth_below_geopotential_datum.json | 2 +- .../standard_name/sea_floor_depth_below_mean_sea_level.json | 2 +- .../sea_floor_depth_below_reference_ellipsoid.json | 2 +- .../standard_name/sea_floor_depth_below_sea_surface.json | 2 +- .../standard_name/sea_floor_sediment_age_before_1950.json | 2 +- .../standard_name/sea_floor_sediment_grain_size.json | 2 +- data_descriptors/standard_name/sea_ice_albedo.json | 2 +- data_descriptors/standard_name/sea_ice_amount.json | 2 +- .../standard_name/sea_ice_and_surface_snow_amount.json | 2 +- data_descriptors/standard_name/sea_ice_area.json | 2 +- data_descriptors/standard_name/sea_ice_area_fraction.json | 2 +- .../standard_name/sea_ice_area_transport_across_line.json | 2 +- .../standard_name/sea_ice_average_normal_horizontal_stress.json | 2 +- ...ea_ice_basal_drag_coefficient_for_momentum_in_sea_water.json | 2 +- data_descriptors/standard_name/sea_ice_basal_temperature.json | 2 +- data_descriptors/standard_name/sea_ice_classification.json | 2 +- data_descriptors/standard_name/sea_ice_draft.json | 2 +- data_descriptors/standard_name/sea_ice_extent.json | 2 +- data_descriptors/standard_name/sea_ice_floe_diameter.json | 2 +- data_descriptors/standard_name/sea_ice_freeboard.json | 2 +- data_descriptors/standard_name/sea_ice_mass.json | 2 +- ..._ice_mass_content_of_ice_algae_expressed_as_chlorophyll.json | 2 +- .../standard_name/sea_ice_mass_content_of_salt.json | 2 +- data_descriptors/standard_name/sea_ice_melt_pond_thickness.json | 2 +- .../sea_ice_mole_content_of_ice_algae_expressed_as_carbon.json | 2 +- .../standard_name/sea_ice_mole_content_of_nitrate.json | 2 +- .../standard_name/sea_ice_mole_content_of_silicon.json | 2 +- data_descriptors/standard_name/sea_ice_salinity.json | 2 +- data_descriptors/standard_name/sea_ice_speed.json | 2 +- data_descriptors/standard_name/sea_ice_surface_temperature.json | 2 +- data_descriptors/standard_name/sea_ice_temperature.json | 2 +- .../sea_ice_temperature_expressed_as_heat_content.json | 2 +- data_descriptors/standard_name/sea_ice_thickness.json | 2 +- .../standard_name/sea_ice_transport_across_line.json | 2 +- data_descriptors/standard_name/sea_ice_volume.json | 2 +- data_descriptors/standard_name/sea_ice_x_displacement.json | 2 +- .../sea_ice_x_force_per_unit_area_due_to_coriolis_effect.json | 2 +- .../sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt.json | 2 +- data_descriptors/standard_name/sea_ice_x_internal_stress.json | 2 +- data_descriptors/standard_name/sea_ice_x_transport.json | 2 +- data_descriptors/standard_name/sea_ice_x_velocity.json | 2 +- data_descriptors/standard_name/sea_ice_y_displacement.json | 2 +- .../sea_ice_y_force_per_unit_area_due_to_coriolis_effect.json | 2 +- .../sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt.json | 2 +- data_descriptors/standard_name/sea_ice_y_internal_stress.json | 2 +- data_descriptors/standard_name/sea_ice_y_transport.json | 2 +- data_descriptors/standard_name/sea_ice_y_velocity.json | 2 +- data_descriptors/standard_name/sea_surface_density.json | 2 +- ...eastward_stress_due_to_dissipation_of_sea_surface_waves.json | 2 +- ...orthward_stress_due_to_dissipation_of_sea_surface_waves.json | 2 +- .../standard_name/sea_surface_foundation_temperature.json | 2 +- .../standard_name/sea_surface_height_above_geoid.json | 2 +- .../sea_surface_height_above_geopotential_datum.json | 2 +- .../standard_name/sea_surface_height_above_mean_sea_level.json | 2 +- .../sea_surface_height_above_reference_ellipsoid.json | 2 +- .../sea_surface_height_amplitude_due_to_earth_tide.json | 2 +- ..._surface_height_amplitude_due_to_equilibrium_ocean_tide.json | 2 +- ...a_surface_height_amplitude_due_to_geocentric_ocean_tide.json | 2 +- ...face_height_amplitude_due_to_non_equilibrium_ocean_tide.json | 2 +- .../sea_surface_height_amplitude_due_to_pole_tide.json | 2 +- .../sea_surface_height_bias_due_to_sea_surface_roughness.json | 2 +- ...rrection_due_to_air_pressure_and_wind_at_high_frequency.json | 2 +- ..._height_correction_due_to_air_pressure_at_low_frequency.json | 2 +- .../sea_surface_infragravity_wave_significant_height.json | 2 +- .../standard_name/sea_surface_mean_square_crosswave_slope.json | 2 +- .../standard_name/sea_surface_mean_square_upwave_slope.json | 2 +- .../sea_surface_mean_square_upwave_slope_direction.json | 2 +- .../sea_surface_primary_swell_wave_directional_spread.json | 2 +- ..._swell_wave_energy_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_primary_swell_wave_from_direction.json | 2 +- ...ave_from_direction_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_primary_swell_wave_mean_period.json | 2 +- ..._swell_wave_period_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_primary_swell_wave_significant_height.json | 2 +- data_descriptors/standard_name/sea_surface_salinity.json | 2 +- .../sea_surface_secondary_swell_wave_directional_spread.json | 2 +- ..._swell_wave_energy_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_secondary_swell_wave_from_direction.json | 2 +- ...ave_from_direction_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_secondary_swell_wave_mean_period.json | 2 +- ..._swell_wave_period_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_secondary_swell_wave_significant_height.json | 2 +- .../standard_name/sea_surface_skin_temperature.json | 2 +- .../standard_name/sea_surface_subskin_temperature.json | 2 +- .../sea_surface_swell_wave_directional_spread.json | 2 +- .../standard_name/sea_surface_swell_wave_from_direction.json | 2 +- ...ave_from_direction_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_swell_wave_mean_period.json | 2 +- ...d_from_variance_spectral_density_first_frequency_moment.json | 2 +- ...from_variance_spectral_density_inverse_frequency_moment.json | 2 +- ..._from_variance_spectral_density_second_frequency_moment.json | 2 +- .../standard_name/sea_surface_swell_wave_period.json | 2 +- ..._swell_wave_period_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_swell_wave_significant_height.json | 2 +- .../standard_name/sea_surface_swell_wave_to_direction.json | 2 +- data_descriptors/standard_name/sea_surface_temperature.json | 2 +- .../sea_surface_tertiary_swell_wave_directional_spread.json | 2 +- ..._swell_wave_energy_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_tertiary_swell_wave_from_direction.json | 2 +- ...ave_from_direction_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_tertiary_swell_wave_mean_period.json | 2 +- ..._swell_wave_period_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_tertiary_swell_wave_significant_height.json | 2 +- .../standard_name/sea_surface_wave_directional_spread.json | 2 +- ...directional_spread_at_variance_spectral_density_maximum.json | 2 +- .../sea_surface_wave_directional_variance_spectral_density.json | 2 +- ...urface_wave_energy_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wave_energy_flux.json | 2 +- ...ace_wave_frequency_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wave_from_direction.json | 2 +- ...ave_from_direction_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wave_maximum_crest_height.json | 2 +- .../standard_name/sea_surface_wave_maximum_height.json | 2 +- .../standard_name/sea_surface_wave_maximum_period.json | 2 +- .../standard_name/sea_surface_wave_maximum_steepness.json | 2 +- .../standard_name/sea_surface_wave_maximum_trough_depth.json | 2 +- .../standard_name/sea_surface_wave_mean_from_direction.json | 2 +- .../standard_name/sea_surface_wave_mean_height.json | 2 +- .../sea_surface_wave_mean_height_of_highest_tenth.json | 2 +- .../standard_name/sea_surface_wave_mean_period.json | 2 +- ...d_from_variance_spectral_density_first_frequency_moment.json | 2 +- ...from_variance_spectral_density_inverse_frequency_moment.json | 2 +- ..._from_variance_spectral_density_second_frequency_moment.json | 2 +- .../sea_surface_wave_mean_period_of_highest_tenth.json | 2 +- .../standard_name/sea_surface_wave_mean_square_slope.json | 2 +- .../standard_name/sea_surface_wave_mean_square_x_slope.json | 2 +- .../standard_name/sea_surface_wave_mean_square_y_slope.json | 2 +- ...rom_variance_spectral_density_inverse_wavenumber_moment.json | 2 +- ..._from_variance_spectral_density_first_wavenumber_moment.json | 2 +- ...urface_wave_period_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wave_period_of_highest_wave.json | 2 +- .../sea_surface_wave_principal_from_direction.json | 2 +- .../standard_name/sea_surface_wave_significant_height.json | 2 +- .../standard_name/sea_surface_wave_significant_period.json | 2 +- .../sea_surface_wave_stokes_drift_eastward_velocity.json | 2 +- .../sea_surface_wave_stokes_drift_northward_velocity.json | 2 +- .../standard_name/sea_surface_wave_stokes_drift_speed.json | 2 +- .../sea_surface_wave_stokes_drift_to_direction.json | 2 +- .../standard_name/sea_surface_wave_stokes_drift_x_velocity.json | 2 +- .../standard_name/sea_surface_wave_stokes_drift_y_velocity.json | 2 +- .../standard_name/sea_surface_wave_to_direction.json | 2 +- .../sea_surface_wave_variance_spectral_density.json | 2 +- .../standard_name/sea_surface_wave_xx_radiation_stress.json | 2 +- .../standard_name/sea_surface_wave_xy_radiation_stress.json | 2 +- .../standard_name/sea_surface_wave_yy_radiation_stress.json | 2 +- .../standard_name/sea_surface_wind_wave_directional_spread.json | 2 +- ...e_wind_wave_energy_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wind_wave_from_direction.json | 2 +- ...ave_from_direction_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wind_wave_mean_period.json | 2 +- ...d_from_variance_spectral_density_first_frequency_moment.json | 2 +- ...from_variance_spectral_density_inverse_frequency_moment.json | 2 +- ..._from_variance_spectral_density_second_frequency_moment.json | 2 +- .../standard_name/sea_surface_wind_wave_period.json | 2 +- ...e_wind_wave_period_at_variance_spectral_density_maximum.json | 2 +- .../standard_name/sea_surface_wind_wave_significant_height.json | 2 +- .../standard_name/sea_surface_wind_wave_to_direction.json | 2 +- data_descriptors/standard_name/sea_water_absolute_salinity.json | 2 +- .../standard_name/sea_water_added_conservative_temperature.json | 2 +- .../standard_name/sea_water_added_potential_temperature.json | 2 +- .../standard_name/sea_water_age_since_surface_contact.json | 2 +- .../sea_water_alkalinity_expressed_as_mole_equivalent.json | 2 +- ...lkalinity_natural_analogue_expressed_as_mole_equivalent.json | 2 +- ...r_alkalinity_per_unit_mass_expressed_as_mole_equivalent.json | 2 +- .../standard_name/sea_water_conservative_temperature.json | 2 +- data_descriptors/standard_name/sea_water_cox_salinity.json | 2 +- data_descriptors/standard_name/sea_water_density.json | 2 +- .../standard_name/sea_water_electrical_conductivity.json | 2 +- ..._water_electrical_conductivity_at_reference_temperature.json | 2 +- data_descriptors/standard_name/sea_water_knudsen_salinity.json | 2 +- data_descriptors/standard_name/sea_water_mass.json | 2 +- .../standard_name/sea_water_mass_per_unit_area.json | 2 +- .../sea_water_mass_per_unit_area_expressed_as_thickness.json | 2 +- data_descriptors/standard_name/sea_water_neutral_density.json | 2 +- .../sea_water_ph_abiotic_analogue_reported_on_total_scale.json | 2 +- .../sea_water_ph_natural_analogue_reported_on_total_scale.json | 2 +- .../standard_name/sea_water_ph_reported_on_total_scale.json | 2 +- data_descriptors/standard_name/sea_water_potential_density.json | 2 +- .../standard_name/sea_water_potential_temperature.json | 2 +- .../sea_water_potential_temperature_at_sea_floor.json | 2 +- ...a_water_potential_temperature_expressed_as_heat_content.json | 2 +- .../standard_name/sea_water_practical_salinity.json | 2 +- .../sea_water_practical_salinity_at_sea_floor.json | 2 +- ...water_preformed_alkalinity_expressed_as_mole_equivalent.json | 2 +- .../standard_name/sea_water_preformed_salinity.json | 2 +- data_descriptors/standard_name/sea_water_pressure.json | 2 +- .../standard_name/sea_water_pressure_at_sea_floor.json | 2 +- .../standard_name/sea_water_pressure_at_sea_water_surface.json | 2 +- .../standard_name/sea_water_pressure_due_to_sea_water.json | 2 +- .../sea_water_redistributed_conservative_temperature.json | 2 +- .../sea_water_redistributed_potential_temperature.json | 2 +- .../standard_name/sea_water_reference_salinity.json | 2 +- data_descriptors/standard_name/sea_water_salinity.json | 2 +- .../standard_name/sea_water_salinity_at_sea_floor.json | 2 +- data_descriptors/standard_name/sea_water_sigma_t.json | 2 +- .../standard_name/sea_water_sigma_t_difference.json | 2 +- data_descriptors/standard_name/sea_water_sigma_theta.json | 2 +- .../standard_name/sea_water_sigma_theta_difference.json | 2 +- .../standard_name/sea_water_specific_potential_enthalpy.json | 2 +- data_descriptors/standard_name/sea_water_speed.json | 2 +- .../standard_name/sea_water_speed_at_sea_floor.json | 2 +- .../standard_name/sea_water_speed_due_to_ekman_drift.json | 2 +- .../standard_name/sea_water_speed_due_to_tides.json | 2 +- data_descriptors/standard_name/sea_water_speed_shear.json | 2 +- data_descriptors/standard_name/sea_water_temperature.json | 2 +- .../standard_name/sea_water_temperature_anomaly.json | 2 +- .../standard_name/sea_water_temperature_at_sea_floor.json | 2 +- .../standard_name/sea_water_temperature_difference.json | 2 +- .../standard_name/sea_water_transport_across_line.json | 2 +- data_descriptors/standard_name/sea_water_turbidity.json | 2 +- .../standard_name/sea_water_velocity_from_direction.json | 2 +- .../standard_name/sea_water_velocity_to_direction.json | 2 +- .../sea_water_velocity_to_direction_at_sea_floor.json | 2 +- .../sea_water_velocity_to_direction_due_to_ekman_drift.json | 2 +- .../sea_water_velocity_to_direction_due_to_tides.json | 2 +- data_descriptors/standard_name/sea_water_volume.json | 2 +- data_descriptors/standard_name/sea_water_volume_fraction.json | 2 +- data_descriptors/standard_name/sea_water_x_velocity.json | 2 +- ..._water_x_velocity_due_to_parameterized_mesoscale_eddies.json | 2 +- data_descriptors/standard_name/sea_water_y_velocity.json | 2 +- ..._water_y_velocity_due_to_parameterized_mesoscale_eddies.json | 2 +- data_descriptors/standard_name/secchi_depth_of_sea_water.json | 2 +- data_descriptors/standard_name/sensor_azimuth_angle.json | 2 +- .../standard_name/sensor_band_central_radiation_frequency.json | 2 +- .../standard_name/sensor_band_central_radiation_wavelength.json | 2 +- .../standard_name/sensor_band_central_radiation_wavenumber.json | 2 +- data_descriptors/standard_name/sensor_band_identifier.json | 2 +- data_descriptors/standard_name/sensor_view_angle.json | 2 +- data_descriptors/standard_name/sensor_zenith_angle.json | 2 +- .../standard_name/shallow_convection_time_fraction.json | 2 +- .../standard_name/shallow_convective_cloud_base_altitude.json | 2 +- .../standard_name/shallow_convective_cloud_top_altitude.json | 2 +- .../standard_name/shallow_convective_precipitation_flux.json | 2 +- .../standard_name/shear_strength_of_frozen_soil.json | 2 +- data_descriptors/standard_name/shear_strength_of_soil.json | 2 +- ...multibeam_acoustic_doppler_velocity_sensor_in_sea_water.json | 2 +- .../standard_name/silicate_mass_transport_in_river_channel.json | 2 +- ...attering_albedo_in_air_due_to_ambient_aerosol_particles.json | 2 +- ...ensing_averaging_kernel_mole_fraction_of_methane_in_air.json | 2 +- ..._kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json | 2 +- ...g_mass_flux_of_particulate_biogenic_silica_in_sea_water.json | 2 +- .../sinking_mass_flux_of_particulate_carbon_in_sea_water.json | 2 +- ..._mass_flux_of_particulate_inorganic_carbon_in_sea_water.json | 2 +- .../sinking_mass_flux_of_particulate_matter_in_sea_water.json | 2 +- .../sinking_mass_flux_of_particulate_nitrogen_in_sea_water.json | 2 +- ...inking_mass_flux_of_particulate_phosphorus_in_sea_water.json | 2 +- ...mole_flux_of_aragonite_expressed_as_carbon_in_sea_water.json | 2 +- ...g_mole_flux_of_calcite_expressed_as_carbon_in_sea_water.json | 2 +- .../sinking_mole_flux_of_particulate_iron_in_sea_water.json | 2 +- ...iculate_organic_matter_expressed_as_carbon_in_sea_water.json | 2 +- ..._mole_flux_of_particulate_organic_nitrogen_in_sea_water.json | 2 +- ...ole_flux_of_particulate_organic_phosphorus_in_sea_water.json | 2 +- .../sinking_mole_flux_of_particulate_silicon_in_sea_water.json | 2 +- .../standard_name/slow_soil_pool_mass_content_of_carbon.json | 2 +- .../standard_name/snow_area_fraction_viewable_from_above.json | 2 +- data_descriptors/standard_name/snow_grain_size.json | 2 +- .../snow_transport_across_line_due_to_sea_ice_dynamics.json | 2 +- data_descriptors/standard_name/snowfall_amount.json | 2 +- data_descriptors/standard_name/snowfall_flux.json | 2 +- data_descriptors/standard_name/soil_albedo.json | 2 +- data_descriptors/standard_name/soil_density.json | 2 +- data_descriptors/standard_name/soil_frozen_water_content.json | 2 +- .../soil_hydraulic_conductivity_at_saturation.json | 2 +- data_descriptors/standard_name/soil_liquid_water_content.json | 2 +- data_descriptors/standard_name/soil_mass_content_of_13C.json | 2 +- data_descriptors/standard_name/soil_mass_content_of_14C.json | 2 +- data_descriptors/standard_name/soil_mass_content_of_carbon.json | 2 +- ...ass_content_of_inorganic_ammonium_expressed_as_nitrogen.json | 2 +- ...mass_content_of_inorganic_nitrate_expressed_as_nitrogen.json | 2 +- ...ass_content_of_inorganic_nitrogen_expressed_as_nitrogen.json | 2 +- .../standard_name/soil_mass_content_of_nitrogen.json | 2 +- .../standard_name/soil_moisture_content_at_field_capacity.json | 2 +- data_descriptors/standard_name/soil_pool.json | 2 +- data_descriptors/standard_name/soil_pool_carbon_decay_rate.json | 2 +- data_descriptors/standard_name/soil_porosity.json | 2 +- data_descriptors/standard_name/soil_suction_at_saturation.json | 2 +- data_descriptors/standard_name/soil_temperature.json | 2 +- data_descriptors/standard_name/soil_thermal_capacity.json | 2 +- data_descriptors/standard_name/soil_thermal_conductivity.json | 2 +- data_descriptors/standard_name/soil_type.json | 2 +- data_descriptors/standard_name/soil_water_ph.json | 2 +- data_descriptors/standard_name/soil_water_salinity.json | 2 +- data_descriptors/standard_name/solar_azimuth_angle.json | 2 +- data_descriptors/standard_name/solar_elevation_angle.json | 2 +- data_descriptors/standard_name/solar_irradiance.json | 2 +- .../standard_name/solar_irradiance_per_unit_wavelength.json | 2 +- data_descriptors/standard_name/solar_zenith_angle.json | 2 +- data_descriptors/standard_name/solid_precipitation_flux.json | 2 +- .../standard_name/solid_precipitation_flux_containing_17O.json | 2 +- .../standard_name/solid_precipitation_flux_containing_18O.json | 2 +- .../solid_precipitation_flux_containing_single_2H.json | 2 +- .../standard_name/soot_content_of_surface_snow.json | 2 +- data_descriptors/standard_name/sound_frequency.json | 2 +- data_descriptors/standard_name/sound_intensity_in_air.json | 2 +- data_descriptors/standard_name/sound_intensity_in_water.json | 2 +- .../standard_name/sound_intensity_level_in_air.json | 2 +- .../standard_name/sound_intensity_level_in_water.json | 2 +- data_descriptors/standard_name/sound_pressure_in_air.json | 2 +- data_descriptors/standard_name/sound_pressure_in_water.json | 2 +- data_descriptors/standard_name/sound_pressure_level_in_air.json | 2 +- .../standard_name/sound_pressure_level_in_water.json | 2 +- data_descriptors/standard_name/source.json | 2 +- data_descriptors/standard_name/specific_dry_energy_of_air.json | 2 +- data_descriptors/standard_name/specific_enthalpy_of_air.json | 2 +- .../standard_name/specific_gravitational_potential_energy.json | 2 +- .../standard_name/specific_heat_capacity_of_frozen_ground.json | 2 +- .../standard_name/specific_heat_capacity_of_sea_water.json | 2 +- data_descriptors/standard_name/specific_humidity.json | 2 +- .../standard_name/specific_kinetic_energy_of_air.json | 2 +- .../standard_name/specific_kinetic_energy_of_sea_water.json | 2 +- ...cific_turbulent_kinetic_energy_dissipation_in_sea_water.json | 2 +- .../standard_name/specific_turbulent_kinetic_energy_of_air.json | 2 +- .../specific_turbulent_kinetic_energy_of_sea_water.json | 2 +- .../spectral_width_of_radio_wave_in_air_scattered_by_air.json | 2 +- .../spectral_width_of_radio_wave_scattered_by_air.json | 2 +- data_descriptors/standard_name/speed_of_sound_in_air.json | 2 +- data_descriptors/standard_name/speed_of_sound_in_sea_water.json | 2 +- ...ell_length_of_days_with_air_temperature_above_threshold.json | 2 +- ...ell_length_of_days_with_air_temperature_below_threshold.json | 2 +- ...h_lwe_thickness_of_precipitation_amount_above_threshold.json | 2 +- ...h_lwe_thickness_of_precipitation_amount_below_threshold.json | 2 +- data_descriptors/standard_name/spike_test_quality_flag.json | 2 +- data_descriptors/standard_name/square_of_air_temperature.json | 2 +- .../standard_name/square_of_brunt_vaisala_frequency_in_air.json | 2 +- .../square_of_brunt_vaisala_frequency_in_sea_water.json | 2 +- data_descriptors/standard_name/square_of_eastward_wind.json | 2 +- .../standard_name/square_of_geopotential_height.json | 2 +- .../square_of_lagrangian_tendency_of_air_pressure.json | 2 +- data_descriptors/standard_name/square_of_northward_wind.json | 2 +- ...quare_of_ocean_mixed_layer_thickness_defined_by_sigma_t.json | 2 +- .../standard_name/square_of_sea_surface_height_above_geoid.json | 2 +- .../standard_name/square_of_sea_surface_salinity.json | 2 +- .../standard_name/square_of_sea_surface_temperature.json | 2 +- .../standard_name/square_of_upward_air_velocity.json | 2 +- .../standard_name/square_of_upward_ocean_mass_transport.json | 2 +- .../standard_name/stagnation_temperature_in_air.json | 2 +- data_descriptors/standard_name/status_flag.json | 2 +- data_descriptors/standard_name/stem_mass_content_of_carbon.json | 2 +- .../standard_name/stem_mass_content_of_nitrogen.json | 2 +- .../standard_name/steric_change_in_mean_sea_level.json | 2 +- .../standard_name/steric_change_in_sea_surface_height.json | 2 +- data_descriptors/standard_name/storm_motion_speed.json | 2 +- .../standard_name/stratiform_cloud_area_fraction.json | 2 +- .../stratiform_cloud_area_fraction_in_atmosphere_layer.json | 2 +- .../standard_name/stratiform_cloud_longwave_emissivity.json | 2 +- .../standard_name/stratiform_graupel_fall_amount.json | 2 +- data_descriptors/standard_name/stratiform_graupel_flux.json | 2 +- .../standard_name/stratiform_precipitation_amount.json | 2 +- .../standard_name/stratiform_precipitation_flux.json | 2 +- data_descriptors/standard_name/stratiform_rainfall_amount.json | 2 +- data_descriptors/standard_name/stratiform_rainfall_flux.json | 2 +- data_descriptors/standard_name/stratiform_rainfall_rate.json | 2 +- data_descriptors/standard_name/stratiform_snowfall_amount.json | 2 +- data_descriptors/standard_name/stratiform_snowfall_flux.json | 2 +- .../stratosphere_mole_content_of_nitrogen_dioxide.json | 2 +- ...here_optical_thickness_due_to_ambient_aerosol_particles.json | 2 +- ...ical_thickness_due_to_sulfate_ambient_aerosol_particles.json | 2 +- ...cal_thickness_due_to_volcanic_ambient_aerosol_particles.json | 2 +- .../standard_name/subsurface_litter_mass_content_of_carbon.json | 2 +- .../subsurface_litter_mass_content_of_nitrogen.json | 2 +- data_descriptors/standard_name/subsurface_runoff_amount.json | 2 +- data_descriptors/standard_name/subsurface_runoff_flux.json | 2 +- data_descriptors/standard_name/sunglint_angle.json | 2 +- data_descriptors/standard_name/sunlit_binary_mask.json | 2 +- data_descriptors/standard_name/surface_air_pressure.json | 2 +- data_descriptors/standard_name/surface_albedo.json | 2 +- .../standard_name/surface_albedo_assuming_deep_snow.json | 2 +- .../standard_name/surface_albedo_assuming_no_snow.json | 2 +- data_descriptors/standard_name/surface_altitude.json | 2 +- .../surface_backwards_scattering_coefficient_of_radar_wave.json | 2 +- .../standard_name/surface_bidirectional_reflectance.json | 2 +- .../standard_name/surface_brightness_temperature.json | 2 +- .../standard_name/surface_buoyancy_flux_into_air.json | 2 +- .../standard_name/surface_buoyancy_flux_into_sea_water.json | 2 +- ...e_partial_pressure_difference_between_sea_water_and_air.json | 2 +- ...e_partial_pressure_difference_between_sea_water_and_air.json | 2 +- ...e_partial_pressure_difference_between_air_and_sea_water.json | 2 +- ...e_partial_pressure_difference_between_sea_water_and_air.json | 2 +- ...iffuse_downwelling_photosynthetic_radiative_flux_in_air.json | 2 +- .../surface_diffuse_downwelling_shortwave_flux_in_air.json | 2 +- ...se_downwelling_shortwave_flux_in_air_assuming_clear_sky.json | 2 +- .../surface_diffuse_shortwave_hemispherical_reflectance.json | 2 +- .../surface_direct_along_beam_shortwave_flux_in_air.json | 2 +- .../surface_direct_downwelling_shortwave_flux_in_air.json | 2 +- .../surface_direct_shortwave_hemispherical_reflectance.json | 2 +- .../standard_name/surface_downward_eastward_stress.json | 2 +- ...e_downward_eastward_stress_due_to_boundary_layer_mixing.json | 2 +- ...wnward_eastward_stress_due_to_ocean_viscous_dissipation.json | 2 +- ...rface_downward_eastward_stress_due_to_sea_surface_waves.json | 2 +- .../standard_name/surface_downward_heat_flux_in_air.json | 2 +- .../standard_name/surface_downward_heat_flux_in_sea_ice.json | 2 +- .../standard_name/surface_downward_heat_flux_in_sea_water.json | 2 +- .../standard_name/surface_downward_heat_flux_in_snow.json | 2 +- .../standard_name/surface_downward_latent_heat_flux.json | 2 +- ...s_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C.json | 2 +- ...lux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon.json | 2 +- .../standard_name/surface_downward_mass_flux_of_ammonia.json | 2 +- ..._of_carbon_dioxide_abiotic_analogue_expressed_as_carbon.json | 2 +- ...ownward_mass_flux_of_carbon_dioxide_expressed_as_carbon.json | 2 +- ..._of_carbon_dioxide_natural_analogue_expressed_as_carbon.json | 2 +- ..._methane_due_to_non_wetland_soil_biological_consumption.json | 2 +- ...mass_flux_of_methane_due_to_soil_biological_consumption.json | 2 +- ...s_flux_of_methane_due_to_wetland_biological_consumption.json | 2 +- .../surface_downward_mass_flux_of_water_due_to_irrigation.json | 2 +- .../surface_downward_mole_flux_of_carbon_dioxide.json | 2 +- .../standard_name/surface_downward_mole_flux_of_cfc11.json | 2 +- .../standard_name/surface_downward_mole_flux_of_cfc12.json | 2 +- .../surface_downward_mole_flux_of_molecular_oxygen.json | 2 +- .../surface_downward_mole_flux_of_sulfur_hexafluoride.json | 2 +- .../standard_name/surface_downward_northward_stress.json | 2 +- ..._downward_northward_stress_due_to_boundary_layer_mixing.json | 2 +- ...nward_northward_stress_due_to_ocean_viscous_dissipation.json | 2 +- ...face_downward_northward_stress_due_to_sea_surface_waves.json | 2 +- .../standard_name/surface_downward_sensible_heat_flux.json | 2 +- data_descriptors/standard_name/surface_downward_water_flux.json | 2 +- data_descriptors/standard_name/surface_downward_x_stress.json | 2 +- .../standard_name/surface_downward_x_stress_correction.json | 2 +- data_descriptors/standard_name/surface_downward_y_stress.json | 2 +- .../standard_name/surface_downward_y_stress_correction.json | 2 +- .../standard_name/surface_downwelling_longwave_flux_in_air.json | 2 +- ...ace_downwelling_longwave_flux_in_air_assuming_clear_sky.json | 2 +- ...g_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json | 2 +- ...in_air_assuming_reference_mole_fraction_of_ozone_in_air.json | 2 +- ...e_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json | 2 +- .../surface_downwelling_photon_flux_in_sea_water.json | 2 +- ...ownwelling_photon_flux_per_unit_wavelength_in_sea_water.json | 2 +- .../surface_downwelling_photon_radiance_in_sea_water.json | 2 +- ...elling_photon_radiance_per_unit_wavelength_in_sea_water.json | 2 +- ...ce_downwelling_photon_spherical_irradiance_in_sea_water.json | 2 +- ...n_spherical_irradiance_per_unit_wavelength_in_sea_water.json | 2 +- .../surface_downwelling_photosynthetic_photon_flux_in_air.json | 2 +- ...ace_downwelling_photosynthetic_photon_flux_in_sea_water.json | 2 +- ...downwelling_photosynthetic_photon_radiance_in_sea_water.json | 2 +- ...photosynthetic_photon_spherical_irradiance_in_sea_water.json | 2 +- ...urface_downwelling_photosynthetic_radiance_in_sea_water.json | 2 +- ...urface_downwelling_photosynthetic_radiative_flux_in_air.json | 2 +- ..._downwelling_photosynthetic_radiative_flux_in_sea_water.json | 2 +- ...elling_photosynthetic_spherical_irradiance_in_sea_water.json | 2 +- .../surface_downwelling_radiance_in_sea_water.json | 2 +- ...e_downwelling_radiance_per_unit_wavelength_in_sea_water.json | 2 +- .../surface_downwelling_radiative_flux_in_sea_water.json | 2 +- ...e_downwelling_radiative_flux_per_unit_wavelength_in_air.json | 2 +- ...welling_radiative_flux_per_unit_wavelength_in_sea_water.json | 2 +- .../surface_downwelling_shortwave_flux_in_air.json | 2 +- ...ce_downwelling_shortwave_flux_in_air_assuming_clear_sky.json | 2 +- ...shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json | 2 +- ...g_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json | 2 +- ...in_air_assuming_reference_mole_fraction_of_ozone_in_air.json | 2 +- ...e_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json | 2 +- .../surface_downwelling_spherical_irradiance_in_sea_water.json | 2 +- ...g_spherical_irradiance_per_unit_wavelength_in_sea_water.json | 2 +- .../standard_name/surface_drag_coefficient_for_heat_in_air.json | 2 +- .../surface_drag_coefficient_for_momentum_in_air.json | 2 +- .../standard_name/surface_drag_coefficient_in_air.json | 2 +- .../standard_name/surface_eastward_sea_water_velocity.json | 2 +- .../standard_name/surface_frozen_carbon_dioxide_amount.json | 2 +- data_descriptors/standard_name/surface_geopotential.json | 2 +- .../surface_geostrophic_eastward_sea_water_velocity.json | 2 +- ...rd_sea_water_velocity_assuming_mean_sea_level_for_geoid.json | 2 +- .../surface_geostrophic_northward_sea_water_velocity.json | 2 +- ...rd_sea_water_velocity_assuming_mean_sea_level_for_geoid.json | 2 +- .../standard_name/surface_geostrophic_sea_water_x_velocity.json | 2 +- ..._sea_water_x_velocity_assuming_mean_sea_level_for_geoid.json | 2 +- .../standard_name/surface_geostrophic_sea_water_y_velocity.json | 2 +- ..._sea_water_y_velocity_assuming_mean_sea_level_for_geoid.json | 2 +- .../standard_name/surface_height_above_geopotential_datum.json | 2 +- .../standard_name/surface_litter_mass_content_of_carbon.json | 2 +- .../standard_name/surface_litter_mass_content_of_nitrogen.json | 2 +- data_descriptors/standard_name/surface_longwave_emissivity.json | 2 +- .../standard_name/surface_microwave_emissivity.json | 2 +- ...n_partial_pressure_difference_between_sea_water_and_air.json | 2 +- ..._dust_ambient_aerosol_particles_direct_radiative_effect.json | 2 +- ...ol_particles_direct_radiative_effect_assuming_clear_sky.json | 2 +- .../standard_name/surface_net_downward_longwave_flux.json | 2 +- .../surface_net_downward_longwave_flux_assuming_clear_sky.json | 2 +- ...s_flux_of_ammonia_due_to_bidirectional_surface_exchange.json | 2 +- ...rbon_dioxide_expressed_as_13C_due_to_all_land_processes.json | 2 +- ...rbon_dioxide_expressed_as_14C_due_to_all_land_processes.json | 2 +- ...n_dioxide_expressed_as_carbon_due_to_all_land_processes.json | 2 +- ..._land_processes_excluding_anthropogenic_land_use_change.json | 2 +- .../standard_name/surface_net_downward_radiative_flux.json | 2 +- ..._dust_ambient_aerosol_particles_direct_radiative_effect.json | 2 +- ...ol_particles_direct_radiative_effect_assuming_clear_sky.json | 2 +- .../standard_name/surface_net_downward_shortwave_flux.json | 2 +- .../surface_net_downward_shortwave_flux_assuming_clear_sky.json | 2 +- .../standard_name/surface_net_upward_longwave_flux.json | 2 +- ...rbon_due_to_emission_from_anthropogenic_land_use_change.json | 2 +- ...thane_due_to_emission_from_wetland_biological_processes.json | 2 +- .../standard_name/surface_net_upward_radiative_flux.json | 2 +- .../standard_name/surface_net_upward_shortwave_flux.json | 2 +- .../standard_name/surface_northward_sea_water_velocity.json | 2 +- ...ressure_of_carbon_dioxide_abiotic_analogue_in_sea_water.json | 2 +- .../surface_partial_pressure_of_carbon_dioxide_in_air.json | 2 +- ...surface_partial_pressure_of_carbon_dioxide_in_sea_water.json | 2 +- ...ressure_of_carbon_dioxide_natural_analogue_in_sea_water.json | 2 +- .../standard_name/surface_radioactivity_content.json | 2 +- .../standard_name/surface_radioactivity_content_of_101Mo.json | 2 +- .../standard_name/surface_radioactivity_content_of_101Tc.json | 2 +- .../standard_name/surface_radioactivity_content_of_102Mo.json | 2 +- .../standard_name/surface_radioactivity_content_of_102Tc.json | 2 +- .../standard_name/surface_radioactivity_content_of_102mTc.json | 2 +- .../standard_name/surface_radioactivity_content_of_103Ru.json | 2 +- .../standard_name/surface_radioactivity_content_of_103mRh.json | 2 +- .../standard_name/surface_radioactivity_content_of_104Tc.json | 2 +- .../standard_name/surface_radioactivity_content_of_105Rh.json | 2 +- .../standard_name/surface_radioactivity_content_of_105Ru.json | 2 +- .../standard_name/surface_radioactivity_content_of_105mRh.json | 2 +- .../standard_name/surface_radioactivity_content_of_106Rh.json | 2 +- .../standard_name/surface_radioactivity_content_of_106Ru.json | 2 +- .../standard_name/surface_radioactivity_content_of_106mRh.json | 2 +- .../standard_name/surface_radioactivity_content_of_107Pd.json | 2 +- .../standard_name/surface_radioactivity_content_of_107Rh.json | 2 +- .../standard_name/surface_radioactivity_content_of_107mPd.json | 2 +- .../standard_name/surface_radioactivity_content_of_109Pd.json | 2 +- .../standard_name/surface_radioactivity_content_of_109mAg.json | 2 +- .../standard_name/surface_radioactivity_content_of_110mAg.json | 2 +- .../standard_name/surface_radioactivity_content_of_111Ag.json | 2 +- .../standard_name/surface_radioactivity_content_of_111Pd.json | 2 +- .../standard_name/surface_radioactivity_content_of_111mAg.json | 2 +- .../standard_name/surface_radioactivity_content_of_111mCd.json | 2 +- .../standard_name/surface_radioactivity_content_of_111mPd.json | 2 +- .../standard_name/surface_radioactivity_content_of_112Ag.json | 2 +- .../standard_name/surface_radioactivity_content_of_112Pd.json | 2 +- .../standard_name/surface_radioactivity_content_of_113Ag.json | 2 +- .../standard_name/surface_radioactivity_content_of_113Cd.json | 2 +- .../standard_name/surface_radioactivity_content_of_113mAg.json | 2 +- .../standard_name/surface_radioactivity_content_of_113mCd.json | 2 +- .../standard_name/surface_radioactivity_content_of_113mIn.json | 2 +- .../standard_name/surface_radioactivity_content_of_115Ag.json | 2 +- .../standard_name/surface_radioactivity_content_of_115Cd.json | 2 +- .../standard_name/surface_radioactivity_content_of_115In.json | 2 +- .../standard_name/surface_radioactivity_content_of_115mAg.json | 2 +- .../standard_name/surface_radioactivity_content_of_115mCd.json | 2 +- .../standard_name/surface_radioactivity_content_of_115mIn.json | 2 +- .../standard_name/surface_radioactivity_content_of_116In.json | 2 +- .../standard_name/surface_radioactivity_content_of_116mIn.json | 2 +- .../standard_name/surface_radioactivity_content_of_117Cd.json | 2 +- .../standard_name/surface_radioactivity_content_of_117In.json | 2 +- .../standard_name/surface_radioactivity_content_of_117mCd.json | 2 +- .../standard_name/surface_radioactivity_content_of_117mIn.json | 2 +- .../standard_name/surface_radioactivity_content_of_117mSn.json | 2 +- .../standard_name/surface_radioactivity_content_of_118Cd.json | 2 +- .../standard_name/surface_radioactivity_content_of_118In.json | 2 +- .../standard_name/surface_radioactivity_content_of_118mIn.json | 2 +- .../standard_name/surface_radioactivity_content_of_119In.json | 2 +- .../standard_name/surface_radioactivity_content_of_119mIn.json | 2 +- .../standard_name/surface_radioactivity_content_of_119mSn.json | 2 +- .../standard_name/surface_radioactivity_content_of_11C.json | 2 +- .../standard_name/surface_radioactivity_content_of_121Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_121mSn.json | 2 +- .../standard_name/surface_radioactivity_content_of_123Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_123mSn.json | 2 +- .../standard_name/surface_radioactivity_content_of_124Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_124mSb.json | 2 +- .../standard_name/surface_radioactivity_content_of_125Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_125Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_125mTe.json | 2 +- .../standard_name/surface_radioactivity_content_of_126Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_126Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_126mSb.json | 2 +- .../standard_name/surface_radioactivity_content_of_127Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_127Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_127Te.json | 2 +- .../standard_name/surface_radioactivity_content_of_127mTe.json | 2 +- .../standard_name/surface_radioactivity_content_of_128Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_128Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_128mSb.json | 2 +- .../standard_name/surface_radioactivity_content_of_129I.json | 2 +- .../standard_name/surface_radioactivity_content_of_129Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_129Te.json | 2 +- .../standard_name/surface_radioactivity_content_of_129mTe.json | 2 +- .../standard_name/surface_radioactivity_content_of_129mXe.json | 2 +- .../standard_name/surface_radioactivity_content_of_130I.json | 2 +- .../standard_name/surface_radioactivity_content_of_130Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_130Sn.json | 2 +- .../standard_name/surface_radioactivity_content_of_130mI.json | 2 +- .../standard_name/surface_radioactivity_content_of_130mSb.json | 2 +- .../standard_name/surface_radioactivity_content_of_131I.json | 2 +- .../standard_name/surface_radioactivity_content_of_131Sb.json | 2 +- .../standard_name/surface_radioactivity_content_of_131Te.json | 2 +- .../standard_name/surface_radioactivity_content_of_131mTe.json | 2 +- .../standard_name/surface_radioactivity_content_of_131mXe.json | 2 +- .../standard_name/surface_radioactivity_content_of_132I.json | 2 +- .../standard_name/surface_radioactivity_content_of_132Te.json | 2 +- .../standard_name/surface_radioactivity_content_of_133I.json | 2 +- .../standard_name/surface_radioactivity_content_of_133Te.json | 2 +- .../standard_name/surface_radioactivity_content_of_133Xe.json | 2 +- .../standard_name/surface_radioactivity_content_of_133mI.json | 2 +- .../standard_name/surface_radioactivity_content_of_133mTe.json | 2 +- .../standard_name/surface_radioactivity_content_of_133mXe.json | 2 +- .../standard_name/surface_radioactivity_content_of_134Cs.json | 2 +- .../standard_name/surface_radioactivity_content_of_134I.json | 2 +- .../standard_name/surface_radioactivity_content_of_134Te.json | 2 +- .../standard_name/surface_radioactivity_content_of_134mCs.json | 2 +- .../standard_name/surface_radioactivity_content_of_134mI.json | 2 +- .../standard_name/surface_radioactivity_content_of_134mXe.json | 2 +- .../standard_name/surface_radioactivity_content_of_135Cs.json | 2 +- .../standard_name/surface_radioactivity_content_of_135I.json | 2 +- .../standard_name/surface_radioactivity_content_of_135Xe.json | 2 +- .../standard_name/surface_radioactivity_content_of_135mBa.json | 2 +- .../standard_name/surface_radioactivity_content_of_135mCs.json | 2 +- .../standard_name/surface_radioactivity_content_of_135mXe.json | 2 +- .../standard_name/surface_radioactivity_content_of_136Cs.json | 2 +- .../standard_name/surface_radioactivity_content_of_137Cs.json | 2 +- .../standard_name/surface_radioactivity_content_of_137Xe.json | 2 +- .../standard_name/surface_radioactivity_content_of_137mBa.json | 2 +- .../standard_name/surface_radioactivity_content_of_138Cs.json | 2 +- .../standard_name/surface_radioactivity_content_of_138Xe.json | 2 +- .../standard_name/surface_radioactivity_content_of_139Ba.json | 2 +- .../standard_name/surface_radioactivity_content_of_13N.json | 2 +- .../standard_name/surface_radioactivity_content_of_140Ba.json | 2 +- .../standard_name/surface_radioactivity_content_of_140La.json | 2 +- .../standard_name/surface_radioactivity_content_of_141Ce.json | 2 +- .../standard_name/surface_radioactivity_content_of_141La.json | 2 +- .../standard_name/surface_radioactivity_content_of_142Ce.json | 2 +- .../standard_name/surface_radioactivity_content_of_142La.json | 2 +- .../standard_name/surface_radioactivity_content_of_142Pr.json | 2 +- .../standard_name/surface_radioactivity_content_of_142mPr.json | 2 +- .../standard_name/surface_radioactivity_content_of_143Ce.json | 2 +- .../standard_name/surface_radioactivity_content_of_143La.json | 2 +- .../standard_name/surface_radioactivity_content_of_143Pr.json | 2 +- .../standard_name/surface_radioactivity_content_of_144Ce.json | 2 +- .../standard_name/surface_radioactivity_content_of_144Nd.json | 2 +- .../standard_name/surface_radioactivity_content_of_144Pr.json | 2 +- .../standard_name/surface_radioactivity_content_of_144mPr.json | 2 +- .../standard_name/surface_radioactivity_content_of_145Pr.json | 2 +- .../standard_name/surface_radioactivity_content_of_146Ce.json | 2 +- .../standard_name/surface_radioactivity_content_of_146Pr.json | 2 +- .../standard_name/surface_radioactivity_content_of_147Nd.json | 2 +- .../standard_name/surface_radioactivity_content_of_147Pm.json | 2 +- .../standard_name/surface_radioactivity_content_of_147Pr.json | 2 +- .../standard_name/surface_radioactivity_content_of_147Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_148Pm.json | 2 +- .../standard_name/surface_radioactivity_content_of_148Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_148mPm.json | 2 +- .../standard_name/surface_radioactivity_content_of_149Nd.json | 2 +- .../standard_name/surface_radioactivity_content_of_149Pm.json | 2 +- .../standard_name/surface_radioactivity_content_of_149Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_150Pm.json | 2 +- .../standard_name/surface_radioactivity_content_of_151Nd.json | 2 +- .../standard_name/surface_radioactivity_content_of_151Pm.json | 2 +- .../standard_name/surface_radioactivity_content_of_151Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_152Nd.json | 2 +- .../standard_name/surface_radioactivity_content_of_152Pm.json | 2 +- .../standard_name/surface_radioactivity_content_of_152mPm.json | 2 +- .../standard_name/surface_radioactivity_content_of_153Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_154Eu.json | 2 +- .../standard_name/surface_radioactivity_content_of_155Eu.json | 2 +- .../standard_name/surface_radioactivity_content_of_155Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_156Eu.json | 2 +- .../standard_name/surface_radioactivity_content_of_156Sm.json | 2 +- .../standard_name/surface_radioactivity_content_of_157Eu.json | 2 +- .../standard_name/surface_radioactivity_content_of_158Eu.json | 2 +- .../standard_name/surface_radioactivity_content_of_159Eu.json | 2 +- .../standard_name/surface_radioactivity_content_of_159Gd.json | 2 +- .../standard_name/surface_radioactivity_content_of_15O.json | 2 +- .../standard_name/surface_radioactivity_content_of_160Tb.json | 2 +- .../standard_name/surface_radioactivity_content_of_161Tb.json | 2 +- .../standard_name/surface_radioactivity_content_of_162Gd.json | 2 +- .../standard_name/surface_radioactivity_content_of_162Tb.json | 2 +- .../standard_name/surface_radioactivity_content_of_162mTb.json | 2 +- .../standard_name/surface_radioactivity_content_of_163Tb.json | 2 +- 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.../standard_name/surface_radioactivity_content_of_240mNp.json | 2 +- .../standard_name/surface_radioactivity_content_of_241Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_241Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_241Pu.json | 2 +- .../standard_name/surface_radioactivity_content_of_242Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_242Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_242Pu.json | 2 +- .../standard_name/surface_radioactivity_content_of_242m1Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_242m2Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_243Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_243Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_243Pu.json | 2 +- .../standard_name/surface_radioactivity_content_of_244Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_244Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_244Pu.json | 2 +- .../standard_name/surface_radioactivity_content_of_244mAm.json | 2 +- .../standard_name/surface_radioactivity_content_of_245Am.json | 2 +- .../standard_name/surface_radioactivity_content_of_245Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_245Pu.json | 2 +- .../standard_name/surface_radioactivity_content_of_246Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_247Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_248Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_249Bk.json | 2 +- .../standard_name/surface_radioactivity_content_of_249Cf.json | 2 +- .../standard_name/surface_radioactivity_content_of_249Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_24Na.json | 2 +- .../standard_name/surface_radioactivity_content_of_250Bk.json | 2 +- .../standard_name/surface_radioactivity_content_of_250Cf.json | 2 +- .../standard_name/surface_radioactivity_content_of_250Cm.json | 2 +- .../standard_name/surface_radioactivity_content_of_251Cf.json | 2 +- .../standard_name/surface_radioactivity_content_of_252Cf.json | 2 +- .../standard_name/surface_radioactivity_content_of_253Cf.json | 2 +- .../standard_name/surface_radioactivity_content_of_253Es.json | 2 +- .../standard_name/surface_radioactivity_content_of_254Cf.json | 2 +- .../standard_name/surface_radioactivity_content_of_254Es.json | 2 +- .../standard_name/surface_radioactivity_content_of_254mEs.json | 2 +- .../standard_name/surface_radioactivity_content_of_255Es.json | 2 +- .../standard_name/surface_radioactivity_content_of_3H.json | 2 +- .../standard_name/surface_radioactivity_content_of_41Ar.json | 2 +- .../standard_name/surface_radioactivity_content_of_54Mn.json | 2 +- .../standard_name/surface_radioactivity_content_of_58Co.json | 2 +- .../standard_name/surface_radioactivity_content_of_60Co.json | 2 +- .../standard_name/surface_radioactivity_content_of_72Ga.json | 2 +- .../standard_name/surface_radioactivity_content_of_72Zn.json | 2 +- .../standard_name/surface_radioactivity_content_of_73Ga.json | 2 +- .../standard_name/surface_radioactivity_content_of_75Ge.json | 2 +- .../standard_name/surface_radioactivity_content_of_77As.json | 2 +- .../standard_name/surface_radioactivity_content_of_77Ge.json | 2 +- .../standard_name/surface_radioactivity_content_of_77mGe.json | 2 +- .../standard_name/surface_radioactivity_content_of_78As.json | 2 +- .../standard_name/surface_radioactivity_content_of_78Ge.json | 2 +- .../standard_name/surface_radioactivity_content_of_79Se.json | 2 +- .../standard_name/surface_radioactivity_content_of_81Se.json | 2 +- .../standard_name/surface_radioactivity_content_of_81mSe.json | 2 +- .../standard_name/surface_radioactivity_content_of_82Br.json | 2 +- .../standard_name/surface_radioactivity_content_of_82mBr.json | 2 +- .../standard_name/surface_radioactivity_content_of_83Br.json | 2 +- .../standard_name/surface_radioactivity_content_of_83Se.json | 2 +- .../standard_name/surface_radioactivity_content_of_83mKr.json | 2 +- .../standard_name/surface_radioactivity_content_of_83mSe.json | 2 +- .../standard_name/surface_radioactivity_content_of_84Br.json | 2 +- .../standard_name/surface_radioactivity_content_of_84mBr.json | 2 +- .../standard_name/surface_radioactivity_content_of_85Kr.json | 2 +- .../standard_name/surface_radioactivity_content_of_85mKr.json | 2 +- .../standard_name/surface_radioactivity_content_of_86Rb.json | 2 +- .../standard_name/surface_radioactivity_content_of_86mRb.json | 2 +- .../standard_name/surface_radioactivity_content_of_87Kr.json | 2 +- .../standard_name/surface_radioactivity_content_of_87Rb.json | 2 +- .../standard_name/surface_radioactivity_content_of_88Kr.json | 2 +- .../standard_name/surface_radioactivity_content_of_88Rb.json | 2 +- .../standard_name/surface_radioactivity_content_of_89Kr.json | 2 +- .../standard_name/surface_radioactivity_content_of_89Rb.json | 2 +- .../standard_name/surface_radioactivity_content_of_89Sr.json | 2 +- .../standard_name/surface_radioactivity_content_of_90Sr.json | 2 +- .../standard_name/surface_radioactivity_content_of_90Y.json | 2 +- .../standard_name/surface_radioactivity_content_of_90mY.json | 2 +- .../standard_name/surface_radioactivity_content_of_91Sr.json | 2 +- .../standard_name/surface_radioactivity_content_of_91Y.json | 2 +- .../standard_name/surface_radioactivity_content_of_91mY.json | 2 +- .../standard_name/surface_radioactivity_content_of_92Sr.json | 2 +- .../standard_name/surface_radioactivity_content_of_92Y.json | 2 +- .../standard_name/surface_radioactivity_content_of_93Y.json | 2 +- .../standard_name/surface_radioactivity_content_of_93Zr.json | 2 +- .../standard_name/surface_radioactivity_content_of_94Nb.json | 2 +- 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data_descriptors/standard_name/surface_snow_area_fraction.json | 2 +- data_descriptors/standard_name/surface_snow_binary_mask.json | 2 +- data_descriptors/standard_name/surface_snow_density.json | 2 +- data_descriptors/standard_name/surface_snow_melt_amount.json | 2 +- .../surface_snow_melt_and_sublimation_heat_flux.json | 2 +- data_descriptors/standard_name/surface_snow_melt_flux.json | 2 +- data_descriptors/standard_name/surface_snow_melt_heat_flux.json | 2 +- .../standard_name/surface_snow_sublimation_amount.json | 2 +- .../standard_name/surface_snow_sublimation_heat_flux.json | 2 +- data_descriptors/standard_name/surface_snow_thickness.json | 2 +- data_descriptors/standard_name/surface_specific_humidity.json | 2 +- data_descriptors/standard_name/surface_temperature.json | 2 +- data_descriptors/standard_name/surface_temperature_anomaly.json | 2 +- ...surface_upward_eastward_stress_due_to_sea_surface_waves.json | 2 +- ...pward_heat_flux_due_to_anthropogenic_energy_consumption.json | 2 +- .../standard_name/surface_upward_heat_flux_in_air.json | 2 +- .../standard_name/surface_upward_latent_heat_flux.json | 2 +- .../surface_upward_latent_heat_flux_due_to_evaporation.json | 2 +- .../surface_upward_latent_heat_flux_due_to_sublimation.json | 2 +- .../standard_name/surface_upward_mass_flux_of_ammonia.json | 2 +- ...oxide_expressed_as_13C_due_to_heterotrophic_respiration.json | 2 +- ...arbon_dioxide_expressed_as_13C_due_to_plant_respiration.json | 2 +- ...oxide_expressed_as_14C_due_to_heterotrophic_respiration.json | 2 +- ...arbon_dioxide_expressed_as_14C_due_to_plant_respiration.json | 2 +- ...rbon_due_to_anthropogenic_land_use_or_land_cover_change.json | 2 +- ...ver_change_excluding_forestry_and_agricultural_products.json | 2 +- ...xpressed_as_carbon_due_to_emission_from_crop_harvesting.json | 2 +- ..._dioxide_expressed_as_carbon_due_to_emission_from_fires.json | 2 +- ...sion_from_fires_excluding_anthropogenic_land_use_change.json | 2 +- 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.../tendency_of_atmosphere_moles_of_alpha_pinene.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_ammonia.json | 2 +- ...sphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json | 2 +- .../tendency_of_atmosphere_moles_of_atomic_bromine.json | 2 +- .../tendency_of_atmosphere_moles_of_atomic_chlorine.json | 2 +- .../tendency_of_atmosphere_moles_of_atomic_nitrogen.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_benzene.json | 2 +- .../tendency_of_atmosphere_moles_of_beta_pinene.json | 2 +- ..._atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json | 2 +- .../tendency_of_atmosphere_moles_of_bromine_chloride.json | 2 +- .../tendency_of_atmosphere_moles_of_bromine_monoxide.json | 2 +- .../tendency_of_atmosphere_moles_of_bromine_nitrate.json | 2 +- ...ndency_of_atmosphere_moles_of_brox_expressed_as_bromine.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_butane.json | 2 +- .../tendency_of_atmosphere_moles_of_carbon_dioxide.json | 2 +- .../tendency_of_atmosphere_moles_of_carbon_monoxide.json | 2 +- .../tendency_of_atmosphere_moles_of_carbon_tetrachloride.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_cfc11.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_cfc113.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_cfc113a.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_cfc114.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_cfc115.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_cfc12.json | 2 +- .../tendency_of_atmosphere_moles_of_chlorine_dioxide.json | 2 +- .../tendency_of_atmosphere_moles_of_chlorine_monoxide.json | 2 +- .../tendency_of_atmosphere_moles_of_chlorine_nitrate.json | 2 +- ...dency_of_atmosphere_moles_of_clox_expressed_as_chlorine.json | 2 +- .../tendency_of_atmosphere_moles_of_dichlorine_peroxide.json | 2 +- .../tendency_of_atmosphere_moles_of_dimethyl_sulfide.json | 2 +- .../tendency_of_atmosphere_moles_of_dinitrogen_pentoxide.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_ethane.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_ethanol.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_ethene.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_ethyne.json | 2 +- .../tendency_of_atmosphere_moles_of_formaldehyde.json | 2 +- .../tendency_of_atmosphere_moles_of_formic_acid.json | 2 +- ...endency_of_atmosphere_moles_of_gaseous_divalent_mercury.json | 2 +- ...ndency_of_atmosphere_moles_of_gaseous_elemental_mercury.json | 2 +- .../tendency_of_atmosphere_moles_of_halon1202.json | 2 +- .../tendency_of_atmosphere_moles_of_halon1211.json | 2 +- .../tendency_of_atmosphere_moles_of_halon1301.json | 2 +- .../tendency_of_atmosphere_moles_of_halon2402.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_hcc140a.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_hcfc141b.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_hcfc142b.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_hcfc22.json | 2 +- .../tendency_of_atmosphere_moles_of_hexachlorobiphenyl.json | 2 +- ...ndency_of_atmosphere_moles_of_hox_expressed_as_hydrogen.json | 2 +- .../tendency_of_atmosphere_moles_of_hydrogen_bromide.json | 2 +- .../tendency_of_atmosphere_moles_of_hydrogen_chloride.json | 2 +- .../tendency_of_atmosphere_moles_of_hydrogen_cyanide.json | 2 +- .../tendency_of_atmosphere_moles_of_hydrogen_peroxide.json | 2 +- .../tendency_of_atmosphere_moles_of_hydroperoxyl_radical.json | 2 +- .../tendency_of_atmosphere_moles_of_hydroxyl_radical.json | 2 +- .../tendency_of_atmosphere_moles_of_hypobromous_acid.json | 2 +- .../tendency_of_atmosphere_moles_of_hypochlorous_acid.json | 2 +- .../tendency_of_atmosphere_moles_of_inorganic_bromine.json | 2 +- .../tendency_of_atmosphere_moles_of_inorganic_chlorine.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_isoprene.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_limonene.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_methane.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_methanol.json | 2 +- .../tendency_of_atmosphere_moles_of_methyl_bromide.json | 2 +- .../tendency_of_atmosphere_moles_of_methyl_chloride.json | 2 +- .../tendency_of_atmosphere_moles_of_methyl_hydroperoxide.json | 2 +- .../tendency_of_atmosphere_moles_of_methyl_peroxy_radical.json | 2 +- .../tendency_of_atmosphere_moles_of_molecular_hydrogen.json | 2 +- .../tendency_of_atmosphere_moles_of_nitrate_radical.json | 2 +- .../tendency_of_atmosphere_moles_of_nitric_acid.json | 2 +- ...les_of_nitric_acid_trihydrate_ambient_aerosol_particles.json | 2 +- .../tendency_of_atmosphere_moles_of_nitrogen_dioxide.json | 2 +- .../tendency_of_atmosphere_moles_of_nitrogen_monoxide.json | 2 +- .../tendency_of_atmosphere_moles_of_nitrous_acid.json | 2 +- .../tendency_of_atmosphere_moles_of_nitrous_oxide.json | 2 +- ...ndency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon.json | 2 +- ...ndency_of_atmosphere_moles_of_nox_expressed_as_nitrogen.json | 2 +- ...ndency_of_atmosphere_moles_of_noy_expressed_as_nitrogen.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_ozone.json | 2 +- .../tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate.json | 2 +- .../tendency_of_atmosphere_moles_of_peroxynitric_acid.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_propane.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_propene.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_radon.json | 2 +- ...cy_of_atmosphere_moles_of_sulfate_dry_aerosol_particles.json | 2 +- .../tendency_of_atmosphere_moles_of_sulfur_dioxide.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_toluene.json | 2 +- .../tendency_of_atmosphere_moles_of_water_vapor.json | 2 +- .../standard_name/tendency_of_atmosphere_moles_of_xylene.json | 2 +- ...mber_content_of_aerosol_particles_due_to_dry_deposition.json | 2 +- ...tent_of_aerosol_particles_due_to_gravitational_settling.json | 2 +- ...ontent_of_aerosol_particles_due_to_turbulent_deposition.json | 2 +- ...mber_content_of_aerosol_particles_due_to_wet_deposition.json | 2 +- ...of_atmosphere_potential_energy_content_due_to_advection.json | 2 +- .../standard_name/tendency_of_bedrock_altitude.json | 2 +- ..._amount_due_to_evaporation_of_intercepted_precipitation.json | 2 +- .../standard_name/tendency_of_change_in_land_ice_amount.json | 2 +- .../tendency_of_dry_energy_content_of_atmosphere_layer.json | 2 +- ...ndency_of_dry_static_energy_content_of_atmosphere_layer.json | 2 +- data_descriptors/standard_name/tendency_of_eastward_wind.json | 2 +- .../tendency_of_eastward_wind_due_to_advection.json | 2 +- ...ion_by_northward_transformed_eulerian_mean_air_velocity.json | 2 +- ...ection_by_upward_transformed_eulerian_mean_air_velocity.json | 2 +- .../tendency_of_eastward_wind_due_to_convection.json | 2 +- .../tendency_of_eastward_wind_due_to_diffusion.json | 2 +- ...y_of_eastward_wind_due_to_eliassen_palm_flux_divergence.json | 2 +- .../tendency_of_eastward_wind_due_to_gravity_wave_drag.json | 2 +- ...of_eastward_wind_due_to_nonorographic_gravity_wave_drag.json | 2 +- .../tendency_of_eastward_wind_due_to_numerical_artefacts.json | 2 +- ...cy_of_eastward_wind_due_to_orographic_gravity_wave_drag.json | 2 +- ...f_enthalpy_content_of_atmosphere_layer_due_to_advection.json | 2 +- .../tendency_of_global_average_sea_level_change.json | 2 +- ...tic_energy_content_of_atmosphere_layer_due_to_advection.json | 2 +- data_descriptors/standard_name/tendency_of_land_ice_mass.json | 2 +- .../tendency_of_land_ice_mass_due_to_basal_mass_balance.json | 2 +- .../standard_name/tendency_of_land_ice_mass_due_to_calving.json | 2 +- .../tendency_of_land_ice_mass_due_to_surface_mass_balance.json | 2 +- .../standard_name/tendency_of_land_ice_thickness.json | 2 +- ..._aerosol_particles_in_air_due_to_emission_from_aviation.json | 2 +- ...f_nitrogen_dioxide_in_air_due_to_emission_from_aviation.json | 2 +- ..._nitrogen_monoxide_in_air_due_to_emission_from_aviation.json | 2 +- ..._nitrogen_monoxide_in_air_due_to_emission_from_aviation.json | 2 +- ...ency_of_mass_content_of_water_vapor_in_atmosphere_layer.json | 2 +- ...nt_of_water_vapor_in_atmosphere_layer_due_to_convection.json | 2 +- ..._water_vapor_in_atmosphere_layer_due_to_deep_convection.json | 2 +- ...ter_vapor_in_atmosphere_layer_due_to_shallow_convection.json | 2 +- ...nt_of_water_vapor_in_atmosphere_layer_due_to_turbulence.json | 2 +- ...ndency_of_mass_fraction_of_cloud_condensed_water_in_air.json | 2 +- ...action_of_cloud_condensed_water_in_air_due_to_advection.json | 2 +- .../tendency_of_mass_fraction_of_cloud_ice_in_air.json | 2 +- ...y_of_mass_fraction_of_cloud_ice_in_air_due_to_advection.json | 2 +- ...y_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion.json | 2 +- .../tendency_of_mass_fraction_of_cloud_liquid_water_in_air.json | 2 +- ..._fraction_of_cloud_liquid_water_in_air_due_to_advection.json | 2 +- ..._fraction_of_cloud_liquid_water_in_air_due_to_diffusion.json | 2 +- ...endency_of_mass_fraction_of_convective_cloud_ice_in_air.json | 2 +- ...f_mass_fraction_of_convective_cloud_liquid_water_in_air.json | 2 +- ...ass_fraction_of_stratiform_cloud_condensed_water_in_air.json | 2 +- ...tratiform_cloud_condensed_water_in_air_due_to_advection.json | 2 +- ...ud_condensed_water_in_air_due_to_autoconversion_to_rain.json | 2 +- ...ud_condensed_water_in_air_due_to_autoconversion_to_snow.json | 2 +- ...oud_condensed_water_in_air_due_to_boundary_layer_mixing.json | 2 +- ..._cloud_condensed_water_in_air_due_to_cloud_microphysics.json | 2 +- ...densed_water_in_air_due_to_condensation_and_evaporation.json | 2 +- ..._stratiform_cloud_condensed_water_in_air_due_to_icefall.json | 2 +- ...endency_of_mass_fraction_of_stratiform_cloud_ice_in_air.json | 2 +- ...of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow.json | 2 +- ...raction_of_stratiform_cloud_ice_in_air_due_to_advection.json | 2 +- ...ction_of_stratiform_cloud_ice_in_air_due_to_aggregation.json | 2 +- ...air_due_to_bergeron_findeisen_process_from_cloud_liquid.json | 2 +- ...tratiform_cloud_ice_in_air_due_to_boundary_layer_mixing.json | 2 +- ...f_stratiform_cloud_ice_in_air_due_to_cloud_microphysics.json | 2 +- ...ratiform_cloud_ice_in_air_due_to_convective_detrainment.json | 2 +- ...form_cloud_ice_in_air_due_to_deposition_and_sublimation.json | 2 +- ...form_cloud_ice_in_air_due_to_evaporation_of_melting_ice.json | 2 +- ...due_to_heterogeneous_nucleation_from_cloud_liquid_water.json | 2 +- ...in_air_due_to_heterogeneous_nucleation_from_water_vapor.json | 2 +- ...ratiform_cloud_ice_in_air_due_to_homogeneous_nucleation.json | 2 +- ..._fraction_of_stratiform_cloud_ice_in_air_due_to_icefall.json | 2 +- ...m_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water.json | 2 +- ...n_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain.json | 2 +- ..._cloud_ice_in_air_due_to_riming_from_cloud_liquid_water.json | 2 +- ..._of_stratiform_cloud_ice_in_air_due_to_riming_from_rain.json | 2 +- ...f_mass_fraction_of_stratiform_cloud_liquid_water_in_air.json | 2 +- ...form_cloud_liquid_water_in_air_due_to_accretion_to_rain.json | 2 +- ...form_cloud_liquid_water_in_air_due_to_accretion_to_snow.json | 2 +- ...f_stratiform_cloud_liquid_water_in_air_due_to_advection.json | 2 +- ...atiform_cloud_liquid_water_in_air_due_to_autoconversion.json | 2 +- ...r_in_air_due_to_bergeron_findeisen_process_to_cloud_ice.json | 2 +- ..._cloud_liquid_water_in_air_due_to_boundary_layer_mixing.json | 2 +- ...orm_cloud_liquid_water_in_air_due_to_cloud_microphysics.json | 2 +- ...liquid_water_in_air_due_to_condensation_and_evaporation.json | 2 +- ...condensation_and_evaporation_from_boundary_layer_mixing.json | 2 +- ...air_due_to_condensation_and_evaporation_from_convection.json | 2 +- ...e_to_condensation_and_evaporation_from_longwave_heating.json | 2 +- ...ue_to_condensation_and_evaporation_from_pressure_change.json | 2 +- ..._to_condensation_and_evaporation_from_shortwave_heating.json | 2 +- ...air_due_to_condensation_and_evaporation_from_turbulence.json | 2 +- ...cloud_liquid_water_in_air_due_to_convective_detrainment.json | 2 +- ...oud_liquid_water_in_air_due_to_heterogeneous_nucleation.json | 2 +- ...cloud_liquid_water_in_air_due_to_homogeneous_nucleation.json | 2 +- ...cloud_liquid_water_in_air_due_to_melting_from_cloud_ice.json | 2 +- ...n_of_stratiform_cloud_liquid_water_in_air_due_to_riming.json | 2 +- .../tendency_of_middle_atmosphere_moles_of_carbon_monoxide.json | 2 +- .../tendency_of_middle_atmosphere_moles_of_hcc140a.json | 2 +- .../tendency_of_middle_atmosphere_moles_of_methane.json | 2 +- .../tendency_of_middle_atmosphere_moles_of_methyl_bromide.json | 2 +- .../tendency_of_middle_atmosphere_moles_of_methyl_chloride.json | 2 +- ...ndency_of_middle_atmosphere_moles_of_molecular_hydrogen.json | 2 +- ...sed_as_carbon_in_sea_water_due_to_biological_production.json | 2 +- ...ite_expressed_as_carbon_in_sea_water_due_to_dissolution.json | 2 +- ...sed_as_carbon_in_sea_water_due_to_biological_production.json | 2 +- ...ite_expressed_as_carbon_in_sea_water_due_to_dissolution.json | 2 +- ...organic_carbon_in_sea_water_due_to_biological_processes.json | 2 +- ...inorganic_iron_in_sea_water_due_to_biological_processes.json | 2 +- ...ganic_nitrogen_in_sea_water_due_to_biological_processes.json | 2 +- ...nic_phosphorus_in_sea_water_due_to_biological_processes.json | 2 +- ...rganic_silicon_in_sea_water_due_to_biological_processes.json | 2 +- ...n_sea_water_due_to_dissolution_from_inorganic_particles.json | 2 +- ...olved_iron_in_sea_water_due_to_grazing_of_phytoplankton.json | 2 +- ...n_in_sea_water_due_to_scavenging_by_inorganic_particles.json | 2 +- ...ation_of_iron_in_sea_water_due_to_biological_production.json | 2 +- ..._of_ox_in_air_due_to_chemical_and_photolytic_production.json | 2 +- ..._concentration_of_ox_in_air_due_to_chemical_destruction.json | 2 +- ..._as_carbon_in_sea_water_due_to_grazing_of_phytoplankton.json | 2 +- ...ed_as_carbon_in_sea_water_due_to_net_primary_production.json | 2 +- ...bon_in_sea_water_due_to_net_primary_production_by_algae.json | 2 +- ...e_to_net_primary_production_by_calcareous_phytoplankton.json | 2 +- ...n_in_sea_water_due_to_net_primary_production_by_diatoms.json | 2 +- ...to_net_primary_production_by_diazotrophic_phytoplankton.json | 2 +- ...o_net_primary_production_by_miscellaneous_phytoplankton.json | 2 +- ...ater_due_to_net_primary_production_by_picophytoplankton.json | 2 +- ...essed_as_carbon_in_sea_water_due_to_nitrate_utilization.json | 2 +- ...xpressed_as_carbon_in_sea_water_due_to_remineralization.json | 2 +- ...on_of_silicon_in_sea_water_due_to_biological_production.json | 2 +- data_descriptors/standard_name/tendency_of_northward_wind.json | 2 +- .../tendency_of_northward_wind_due_to_advection.json | 2 +- .../tendency_of_northward_wind_due_to_convection.json | 2 +- .../tendency_of_northward_wind_due_to_diffusion.json | 2 +- .../tendency_of_northward_wind_due_to_gravity_wave_drag.json | 2 +- ...f_northward_wind_due_to_nonorographic_gravity_wave_drag.json | 2 +- ...y_of_northward_wind_due_to_orographic_gravity_wave_drag.json | 2 +- .../tendency_of_ocean_barotropic_streamfunction.json | 2 +- ...etic_energy_content_due_to_parameterized_eddy_advection.json | 2 +- ...gonite_expressed_as_carbon_due_to_biological_production.json | 2 +- ...alcite_expressed_as_carbon_due_to_biological_production.json | 2 +- ...ontent_of_carbon_due_to_runoff_and_sediment_dissolution.json | 2 +- ...cy_of_ocean_mole_content_of_carbon_due_to_sedimentation.json | 2 +- ...ncy_of_ocean_mole_content_of_dissolved_inorganic_carbon.json | 2 +- ..._dissolved_inorganic_carbon_due_to_biological_processes.json | 2 +- ...dency_of_ocean_mole_content_of_dissolved_inorganic_iron.json | 2 +- ...of_dissolved_inorganic_iron_due_to_biological_processes.json | 2 +- ...y_of_ocean_mole_content_of_dissolved_inorganic_nitrogen.json | 2 +- ...issolved_inorganic_nitrogen_due_to_biological_processes.json | 2 +- ...of_ocean_mole_content_of_dissolved_inorganic_phosphorus.json | 2 +- ...solved_inorganic_phosphorus_due_to_biological_processes.json | 2 +- ...cy_of_ocean_mole_content_of_dissolved_inorganic_silicon.json | 2 +- ...dissolved_inorganic_silicon_due_to_biological_processes.json | 2 +- ...ental_nitrogen_due_to_denitrification_and_sedimentation.json | 2 +- ...ntal_nitrogen_due_to_deposition_and_fixation_and_runoff.json | 2 +- ...cean_mole_content_of_elemental_nitrogen_due_to_fixation.json | 2 +- .../tendency_of_ocean_mole_content_of_inorganic_carbon.json | 2 +- ...inorganic_carbon_due_to_runoff_and_sediment_dissolution.json | 2 +- ...n_mole_content_of_inorganic_carbon_due_to_sedimentation.json | 2 +- ...ocean_mole_content_of_iron_due_to_biological_production.json | 2 +- ...n_due_to_deposition_and_runoff_and_sediment_dissolution.json | 2 +- ...ency_of_ocean_mole_content_of_iron_due_to_sedimentation.json | 2 +- ...n_mole_content_of_nitrogen_due_to_biological_production.json | 2 +- ...f_organic_carbon_due_to_runoff_and_sediment_dissolution.json | 2 +- ...ean_mole_content_of_organic_carbon_due_to_sedimentation.json | 2 +- ...rogen_compounds_expressed_as_nitrogen_due_to_deposition.json | 2 +- ...n_compounds_expressed_as_nitrogen_due_to_dry_deposition.json | 2 +- ...n_compounds_expressed_as_nitrogen_due_to_wet_deposition.json | 2 +- ...mole_content_of_phosphorus_due_to_biological_production.json | 2 +- ...rogen_compounds_expressed_as_nitrogen_due_to_deposition.json | 2 +- ...n_compounds_expressed_as_nitrogen_due_to_dry_deposition.json | 2 +- ...n_compounds_expressed_as_nitrogen_due_to_wet_deposition.json | 2 +- ...an_mole_content_of_silicon_due_to_biological_production.json | 2 +- .../tendency_of_ocean_potential_energy_content.json | 2 +- ...ncy_of_ocean_potential_energy_content_due_to_background.json | 2 +- ...tendency_of_ocean_potential_energy_content_due_to_tides.json | 2 +- ...ial_energy_content_of_atmosphere_layer_due_to_advection.json | 2 +- ...tential_energy_content_of_ocean_layer_due_to_convection.json | 2 +- ...otential_energy_content_of_ocean_layer_due_to_diffusion.json | 2 +- .../tendency_of_sea_ice_amount_due_to_basal_melting.json | 2 +- ...y_of_sea_ice_amount_due_to_congelation_ice_accumulation.json | 2 +- ..._of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice.json | 2 +- ..._sea_ice_amount_due_to_frazil_ice_accumulation_in_leads.json | 2 +- ...cy_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes.json | 2 +- .../tendency_of_sea_ice_amount_due_to_lateral_melting.json | 2 +- .../tendency_of_sea_ice_amount_due_to_sea_ice_dynamics.json | 2 +- ...endency_of_sea_ice_amount_due_to_sea_ice_thermodynamics.json | 2 +- .../tendency_of_sea_ice_amount_due_to_surface_melting.json | 2 +- .../tendency_of_sea_ice_area_fraction_due_to_dynamics.json | 2 +- .../tendency_of_sea_ice_area_fraction_due_to_ridging.json | 2 +- ...tendency_of_sea_ice_area_fraction_due_to_thermodynamics.json | 2 +- .../tendency_of_sea_ice_thickness_due_to_dynamics.json | 2 +- .../tendency_of_sea_ice_thickness_due_to_thermodynamics.json | 2 +- .../tendency_of_sea_surface_height_above_mean_sea_level.json | 2 +- ...xpressed_as_mole_equivalent_due_to_biological_processes.json | 2 +- ...ater_conservative_temperature_expressed_as_heat_content.json | 2 +- ..._as_heat_content_due_to_parameterized_dianeutral_mixing.json | 2 +- ...sed_as_heat_content_due_to_parameterized_eddy_advection.json | 2 +- ...t_content_due_to_parameterized_mesoscale_eddy_advection.json | 2 +- 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..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...tive_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...iative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...adiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...e_absorption_coefficient_of_radiative_flux_in_sea_water.json | 2 +- ...ative_flux_in_sea_water_due_to_dissolved_organic_matter.json | 2 +- ...ckwards_scattering_coefficient_of_radiative_flux_in_air.json | 2 +- ...t_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud.json | 2 +- ..._coefficient_of_downwelling_radiative_flux_in_sea_water.json | 2 +- ...ging_instrument_in_air_due_to_ambient_aerosol_particles.json | 2 +- ...cient_of_radiative_flux_in_air_due_to_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ..._radiative_flux_in_air_due_to_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...of_radiative_flux_in_air_due_to_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...t_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ..._of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...ative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...diative_flux_in_air_due_to_pm10_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...t_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...iative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...adiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ..._radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...tive_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...iative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...adiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...s_scattering_coefficient_of_radiative_flux_in_sea_water.json | 2 +- ..._attenuation_coefficient_of_radiative_flux_in_sea_water.json | 2 +- ...e_flux_in_sea_water_corrected_for_pure_water_attenuance.json | 2 +- ...gstrom_exponent_in_air_due_to_ambient_aerosol_particles.json | 2 +- ..._radiative_flux_in_air_due_to_ambient_aerosol_particles.json | 2 +- ...ficient_of_radiative_flux_in_air_due_to_cloud_particles.json | 2 +- .../standard_name/volume_fraction_of_clay_in_soil.json | 2 +- .../volume_fraction_of_condensed_water_in_soil.json | 2 +- ...e_fraction_of_condensed_water_in_soil_at_critical_point.json | 2 +- ...e_fraction_of_condensed_water_in_soil_at_field_capacity.json | 2 +- ...me_fraction_of_condensed_water_in_soil_at_wilting_point.json | 2 +- .../volume_fraction_of_condensed_water_in_soil_pores.json | 2 +- .../standard_name/volume_fraction_of_frozen_water_in_soil.json | 2 +- ...ume_fraction_of_oxygen_in_sea_floor_sediment_pore_water.json | 2 +- .../standard_name/volume_fraction_of_oxygen_in_sea_water.json | 2 +- .../volume_fraction_of_pelite_in_sea_floor_sediment.json | 2 +- .../standard_name/volume_fraction_of_sand_in_soil.json | 2 +- .../standard_name/volume_fraction_of_silt_in_soil.json | 2 +- .../volume_fraction_of_water_in_soil_at_saturation.json | 2 +- .../volume_mixing_ratio_of_oxygen_at_stp_in_sea_water.json | 2 +- ...cient_of_radiative_flux_in_air_due_to_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ..._radiative_flux_in_air_due_to_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...of_radiative_flux_in_air_due_to_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...t_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ..._of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...ative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...diative_flux_in_air_due_to_pm10_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...t_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...iative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...adiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ..._radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...tive_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...iative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...adiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json | 2 +- ..._aerosol_particles_at_standard_temperature_and_pressure.json | 2 +- ...e_scattering_coefficient_of_radiative_flux_in_sea_water.json | 2 +- ..._radiative_flux_in_air_due_to_ambient_aerosol_particles.json | 2 +- ...lume_scattering_function_of_radiative_flux_in_sea_water.json | 2 +- data_descriptors/standard_name/water_evaporation_amount.json | 2 +- .../standard_name/water_evaporation_amount_from_canopy.json | 2 +- .../standard_name/water_evaporation_flux_from_canopy.json | 2 +- .../standard_name/water_evaporation_flux_from_soil.json | 2 +- .../standard_name/water_evapotranspiration_amount.json | 2 +- .../standard_name/water_evapotranspiration_flux.json | 2 +- data_descriptors/standard_name/water_flux_into_sea_water.json | 2 +- .../water_flux_into_sea_water_due_to_flux_adjustment.json | 2 +- ...water_flux_into_sea_water_due_to_sea_ice_thermodynamics.json | 2 +- .../water_flux_into_sea_water_due_to_surface_drainage.json | 2 +- .../standard_name/water_flux_into_sea_water_from_icebergs.json | 2 +- .../standard_name/water_flux_into_sea_water_from_land_ice.json | 2 +- .../standard_name/water_flux_into_sea_water_from_rivers.json | 2 +- ...o_sea_water_from_rivers_and_surface_downward_water_flux.json | 2 +- .../water_flux_into_sea_water_without_flux_correction.json | 2 +- .../standard_name/water_flux_out_of_sea_ice_and_sea_water.json | 2 +- data_descriptors/standard_name/water_flux_out_of_sea_water.json | 2 +- ...water_flux_out_of_sea_water_due_to_newtonian_relaxation.json | 2 +- ...ter_flux_out_of_sea_water_due_to_sea_ice_thermodynamics.json | 2 +- .../standard_name/water_potential_evaporation_amount.json | 2 +- .../standard_name/water_potential_evaporation_flux.json | 2 +- .../water_potential_evapotranspiration_amount.json | 2 +- data_descriptors/standard_name/water_sublimation_flux.json | 2 +- .../water_surface_height_above_reference_datum.json | 2 +- .../standard_name/water_surface_reference_datum_altitude.json | 2 +- data_descriptors/standard_name/water_table_depth.json | 2 +- .../standard_name/water_vapor_partial_pressure_in_air.json | 2 +- .../standard_name/water_vapor_saturation_deficit_in_air.json | 2 +- .../standard_name/water_volume_transport_in_river_channel.json | 2 +- .../water_volume_transport_into_sea_water_from_rivers.json | 2 +- data_descriptors/standard_name/wave_frequency.json | 2 +- .../westward_upward_derivative_of_geopotential.json | 2 +- .../westward_westward_derivative_of_geopotential.json | 2 +- .../standard_name/wet_bulb_potential_temperature.json | 2 +- data_descriptors/standard_name/wet_bulb_temperature.json | 2 +- .../standard_name/wind_chill_of_air_temperature.json | 2 +- data_descriptors/standard_name/wind_from_direction.json | 2 +- data_descriptors/standard_name/wind_gust_from_direction.json | 2 +- .../standard_name/wind_mixing_energy_flux_into_sea_water.json | 2 +- data_descriptors/standard_name/wind_speed.json | 2 +- data_descriptors/standard_name/wind_speed_of_gust.json | 2 +- .../standard_name/wind_speed_of_gust_due_to_convection.json | 2 +- .../standard_name/wind_speed_of_gust_due_to_turbulence.json | 2 +- data_descriptors/standard_name/wind_speed_shear.json | 2 +- data_descriptors/standard_name/wind_to_direction.json | 2 +- .../standard_name/wood_debris_mass_content_of_carbon.json | 2 +- .../standard_name/wood_debris_mass_content_of_nitrogen.json | 2 +- .../standard_name/x_derivative_of_ocean_rigid_lid_pressure.json | 2 +- .../x_heat_flux_in_sea_water_due_to_advection.json | 2 +- data_descriptors/standard_name/x_wind.json | 2 +- data_descriptors/standard_name/x_wind_gust.json | 2 +- .../standard_name/y_derivative_of_ocean_rigid_lid_pressure.json | 2 +- .../y_heat_flux_in_sea_water_due_to_advection.json | 2 +- data_descriptors/standard_name/y_wind.json | 2 +- data_descriptors/standard_name/y_wind_gust.json | 2 +- data_descriptors/standard_name/zenith_angle.json | 2 +- 4947 files changed, 4947 insertions(+), 4947 deletions(-) diff --git a/data_descriptors/area_type_table/air.json b/data_descriptors/area_type_table/air.json index 1f40fc56c..2f51d32ce 100644 --- a/data_descriptors/area_type_table/air.json +++ b/data_descriptors/area_type_table/air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/air", + "id": "air", "type": "area-type-table", "name": "air", "description": "The area type of \"air\" distinguishes the atmospheric portion of a domain from the land portion (or any other non-air portion). It is needed when a variable such as wind speed is reported, for example, on a surface at mean sea level pressure. At most locations over land, this surface would be underground and would need to be excluded from consideration, which could be indicated by specifying a cell_ methods \"where air\"." diff --git a/data_descriptors/area_type_table/all_area_types.json b/data_descriptors/area_type_table/all_area_types.json index f1e6fc9ad..bab9a4771 100644 --- a/data_descriptors/area_type_table/all_area_types.json +++ b/data_descriptors/area_type_table/all_area_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/all_area_types", + "id": "all_area_types", "type": "area-type-table", "name": "all_area_types", "description": null diff --git a/data_descriptors/area_type_table/bare_ground.json b/data_descriptors/area_type_table/bare_ground.json index ea74a4e9e..8d501f202 100644 --- a/data_descriptors/area_type_table/bare_ground.json +++ b/data_descriptors/area_type_table/bare_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/bare_ground", + "id": "bare_ground", "type": "area-type-table", "name": "bare_ground", "description": null diff --git a/data_descriptors/area_type_table/burnt_vegetation.json b/data_descriptors/area_type_table/burnt_vegetation.json index 605feeccc..3323ea8e4 100644 --- a/data_descriptors/area_type_table/burnt_vegetation.json +++ b/data_descriptors/area_type_table/burnt_vegetation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/burnt_vegetation", + "id": "burnt_vegetation", "type": "area-type-table", "name": "burnt_vegetation", "description": null diff --git a/data_descriptors/area_type_table/c3_plant_functional_types.json b/data_descriptors/area_type_table/c3_plant_functional_types.json index c69195483..529a9f47a 100644 --- a/data_descriptors/area_type_table/c3_plant_functional_types.json +++ b/data_descriptors/area_type_table/c3_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/c3_plant_functional_types", + "id": "c3_plant_functional_types", "type": "area-type-table", "name": "c3_plant_functional_types", "description": "A plant that utilizes the C3 carbon fixation pathway as the sole mechanism to bind CO2 before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/c4_plant_functional_types.json b/data_descriptors/area_type_table/c4_plant_functional_types.json index 0716d5ba1..8a2a58a04 100644 --- a/data_descriptors/area_type_table/c4_plant_functional_types.json +++ b/data_descriptors/area_type_table/c4_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/c4_plant_functional_types", + "id": "c4_plant_functional_types", "type": "area-type-table", "name": "c4_plant_functional_types", "description": "A plant that utilizes the C4 carbon fixation pathway in which the CO2 is first bound to a compound containing four carbon atoms before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/clear_sky.json b/data_descriptors/area_type_table/clear_sky.json index 2d364877a..74a98d156 100644 --- a/data_descriptors/area_type_table/clear_sky.json +++ b/data_descriptors/area_type_table/clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/clear_sky", + "id": "clear_sky", "type": "area-type-table", "name": "clear_sky", "description": null diff --git a/data_descriptors/area_type_table/cloud.json b/data_descriptors/area_type_table/cloud.json index cc88f0134..33e7b91ff 100644 --- a/data_descriptors/area_type_table/cloud.json +++ b/data_descriptors/area_type_table/cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/cloud", + "id": "cloud", "type": "area-type-table", "name": "cloud", "description": "The \"cloud\" area type is a general term and includes both convective_cloud and stratiform_cloud types and any additional cloud areas that are not separately named." diff --git a/data_descriptors/area_type_table/convective_cloud.json b/data_descriptors/area_type_table/convective_cloud.json index 794502479..ef1e7c31d 100644 --- a/data_descriptors/area_type_table/convective_cloud.json +++ b/data_descriptors/area_type_table/convective_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/convective_cloud", + "id": "convective_cloud", "type": "area-type-table", "name": "convective_cloud", "description": "This area type complements the \"stratiform_cloud\" area type, which is the other major category of cloud. The \"cloud\" area type is a more general term and includes both convective_cloud and stratiform_cloud types." diff --git a/data_descriptors/area_type_table/crops.json b/data_descriptors/area_type_table/crops.json index bc800091f..ad6cfaeac 100644 --- a/data_descriptors/area_type_table/crops.json +++ b/data_descriptors/area_type_table/crops.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/crops", + "id": "crops", "type": "area-type-table", "name": "crops", "description": "The definition of \"crops\" is model dependent, for example, some models may include fruit trees as crops." diff --git a/data_descriptors/area_type_table/crops_of_c3_plant_functional_types.json b/data_descriptors/area_type_table/crops_of_c3_plant_functional_types.json index 054577dea..c9916ccc9 100644 --- a/data_descriptors/area_type_table/crops_of_c3_plant_functional_types.json +++ b/data_descriptors/area_type_table/crops_of_c3_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/crops_of_c3_plant_functional_types", + "id": "crops_of_c3_plant_functional_types", "type": "area-type-table", "name": "crops_of_c3_plant_functional_types", "description": "The definition of \"crops\" is model dependent, for example, some models may include fruit trees as crops. A \"c3 plant\" is one that utilizes the C3 carbon fixation pathway as the sole mechanism to bind CO2 before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/crops_of_c4_plant_functional_types.json b/data_descriptors/area_type_table/crops_of_c4_plant_functional_types.json index d9ac445e6..890d252a5 100644 --- a/data_descriptors/area_type_table/crops_of_c4_plant_functional_types.json +++ b/data_descriptors/area_type_table/crops_of_c4_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/crops_of_c4_plant_functional_types", + "id": "crops_of_c4_plant_functional_types", "type": "area-type-table", "name": "crops_of_c4_plant_functional_types", "description": "The definition of \"crops\" is model dependent, for example, some models may include fruit trees as crops. A \"c4 plant\" is one that utilizes the C4 carbon fixation pathway in which the CO2 is first bound to a compound containing four carbon atoms before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/dust_aerosol.json b/data_descriptors/area_type_table/dust_aerosol.json index 8f58755c2..8807adf85 100644 --- a/data_descriptors/area_type_table/dust_aerosol.json +++ b/data_descriptors/area_type_table/dust_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/dust_aerosol", + "id": "dust_aerosol", "type": "area-type-table", "name": "dust_aerosol", "description": "An area_type of \"dust_aerosol\" indicates that dust aerosol is present at some level in the atmospheric column above an area on the surface of the Earth." diff --git a/data_descriptors/area_type_table/fire.json b/data_descriptors/area_type_table/fire.json index 7af6e4275..cba2b0b12 100644 --- a/data_descriptors/area_type_table/fire.json +++ b/data_descriptors/area_type_table/fire.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/fire", + "id": "fire", "type": "area-type-table", "name": "fire", "description": "An area_type of \"fire\" indicates that biomass fire, either flaming, smouldering, or both, is present." diff --git a/data_descriptors/area_type_table/floating_ice.json b/data_descriptors/area_type_table/floating_ice.json index b5266b83f..7fe5aff80 100644 --- a/data_descriptors/area_type_table/floating_ice.json +++ b/data_descriptors/area_type_table/floating_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/floating_ice", + "id": "floating_ice", "type": "area-type-table", "name": "floating_ice", "description": "All ice floating on water including lake-ice, sea-ice, ice-shelves and icebergs." diff --git a/data_descriptors/area_type_table/floating_ice_shelf.json b/data_descriptors/area_type_table/floating_ice_shelf.json index 630c6345e..c7a56cd98 100644 --- a/data_descriptors/area_type_table/floating_ice_shelf.json +++ b/data_descriptors/area_type_table/floating_ice_shelf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/floating_ice_shelf", + "id": "floating_ice_shelf", "type": "area-type-table", "name": "floating_ice_shelf", "description": "An area type of \"floating ice shelf\" indicates where ice shelves are present. Ice shelves are the component of ice sheets that flow over the ocean." diff --git a/data_descriptors/area_type_table/fresh_free_water.json b/data_descriptors/area_type_table/fresh_free_water.json index b36399d6d..48035a67b 100644 --- a/data_descriptors/area_type_table/fresh_free_water.json +++ b/data_descriptors/area_type_table/fresh_free_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/fresh_free_water", + "id": "fresh_free_water", "type": "area-type-table", "name": "fresh_free_water", "description": "An area type of \"fresh_free_water\" means a free interface between freshwater and the atmosphere without vegetation or other obstructions." diff --git a/data_descriptors/area_type_table/grounded_ice_sheet.json b/data_descriptors/area_type_table/grounded_ice_sheet.json index d907c9805..5b09fa25e 100644 --- a/data_descriptors/area_type_table/grounded_ice_sheet.json +++ b/data_descriptors/area_type_table/grounded_ice_sheet.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/grounded_ice_sheet", + "id": "grounded_ice_sheet", "type": "area-type-table", "name": "grounded_ice_sheet", "description": "An area type of \"grounded ice sheet\" indicates where the ice sheet rest over bedrock and is thus grounded. It excludes ice-caps, glaciers and floating ice shelves." diff --git a/data_descriptors/area_type_table/herbaceous_vegetation.json b/data_descriptors/area_type_table/herbaceous_vegetation.json index 426194d5a..ebf8b9a60 100644 --- a/data_descriptors/area_type_table/herbaceous_vegetation.json +++ b/data_descriptors/area_type_table/herbaceous_vegetation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/herbaceous_vegetation", + "id": "herbaceous_vegetation", "type": "area-type-table", "name": "herbaceous_vegetation", "description": "Herbaceous plants are plants with very flexible stems. Their leaves and stems die down to soil level at the end of every growing season. Herbaceous plants can be annual, biennial or perennial." diff --git a/data_descriptors/area_type_table/ice_and_snow_on_land.json b/data_descriptors/area_type_table/ice_and_snow_on_land.json index cd260d966..215daa9ed 100644 --- a/data_descriptors/area_type_table/ice_and_snow_on_land.json +++ b/data_descriptors/area_type_table/ice_and_snow_on_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/ice_and_snow_on_land", + "id": "ice_and_snow_on_land", "type": "area-type-table", "name": "ice_and_snow_on_land", "description": "The area type \"ice_and_snow_on_land\" means ice in glaciers, ice caps, ice sheets (grounded and floating shelves), river and lake ice, any other ice on a land surface, such as frozen flood water, and snow lying on such ice or on the land surface." diff --git a/data_descriptors/area_type_table/ice_free_land.json b/data_descriptors/area_type_table/ice_free_land.json index da8ce59a1..e580be842 100644 --- a/data_descriptors/area_type_table/ice_free_land.json +++ b/data_descriptors/area_type_table/ice_free_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/ice_free_land", + "id": "ice_free_land", "type": "area-type-table", "name": "ice_free_land", "description": null diff --git a/data_descriptors/area_type_table/ice_free_sea.json b/data_descriptors/area_type_table/ice_free_sea.json index 0a8c2759d..e83ad1810 100644 --- a/data_descriptors/area_type_table/ice_free_sea.json +++ b/data_descriptors/area_type_table/ice_free_sea.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/ice_free_sea", + "id": "ice_free_sea", "type": "area-type-table", "name": "ice_free_sea", "description": null diff --git a/data_descriptors/area_type_table/ice_on_land.json b/data_descriptors/area_type_table/ice_on_land.json index 7847cb446..4d184656c 100644 --- a/data_descriptors/area_type_table/ice_on_land.json +++ b/data_descriptors/area_type_table/ice_on_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/ice_on_land", + "id": "ice_on_land", "type": "area-type-table", "name": "ice_on_land", "description": "The area type \"ice_on_land\" means ice in glaciers, ice caps, grounded ice sheets (grounded and floating shelves), river and lake ice, and any other ice on a land surface, such as frozen flood water. This is distinct from the area type 'land ice' which has a narrower definition." diff --git a/data_descriptors/area_type_table/ice_sheet.json b/data_descriptors/area_type_table/ice_sheet.json index 42c2e1996..395aafcd6 100644 --- a/data_descriptors/area_type_table/ice_sheet.json +++ b/data_descriptors/area_type_table/ice_sheet.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/ice_sheet", + "id": "ice_sheet", "type": "area-type-table", "name": "ice_sheet", "description": "An area type of \"ice_sheet\" indicates where ice sheets are present. It includes both grounded ice sheets resting over bedrock and any ice shelves flowing over the ocean that are attached to grounded ice sheets. The ice_sheet area type excludes ice-caps and glaciers and any floating ice shelves and ice tongues attached to them, but the land_ice area type includes those as well as the ice_sheet area." diff --git a/data_descriptors/area_type_table/lake_ice_or_sea_ice.json b/data_descriptors/area_type_table/lake_ice_or_sea_ice.json index ffcc73a42..1a23e5441 100644 --- a/data_descriptors/area_type_table/lake_ice_or_sea_ice.json +++ b/data_descriptors/area_type_table/lake_ice_or_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/lake_ice_or_sea_ice", + "id": "lake_ice_or_sea_ice", "type": "area-type-table", "name": "lake_ice_or_sea_ice", "description": "Floating ice excluding ice-shelves and icebergs." diff --git a/data_descriptors/area_type_table/land.json b/data_descriptors/area_type_table/land.json index 735b4566e..b695d5e95 100644 --- a/data_descriptors/area_type_table/land.json +++ b/data_descriptors/area_type_table/land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/land", + "id": "land", "type": "area-type-table", "name": "land", "description": null diff --git a/data_descriptors/area_type_table/land_ice.json b/data_descriptors/area_type_table/land_ice.json index b3b3e9381..a9984f6db 100644 --- a/data_descriptors/area_type_table/land_ice.json +++ b/data_descriptors/area_type_table/land_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/land_ice", + "id": "land_ice", "type": "area-type-table", "name": "land_ice", "description": "\"Land ice\" means glaciers, ice-caps, grounded ice sheets resting on bedrock and floating ice-shelves." diff --git a/data_descriptors/area_type_table/melt_pond_free_sea_ice.json b/data_descriptors/area_type_table/melt_pond_free_sea_ice.json index ffc62be80..dfaa4c0bf 100644 --- a/data_descriptors/area_type_table/melt_pond_free_sea_ice.json +++ b/data_descriptors/area_type_table/melt_pond_free_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/melt_pond_free_sea_ice", + "id": "melt_pond_free_sea_ice", "type": "area-type-table", "name": "melt_pond_free_sea_ice", "description": "The area occupied by type \"sea_ice\" is the sum of the areas of types \"sea_ice_melt_pond\" and \"melt_pond_free_sea_ice\"." diff --git a/data_descriptors/area_type_table/natural_grasses.json b/data_descriptors/area_type_table/natural_grasses.json index a6d73f7ba..56203dfdf 100644 --- a/data_descriptors/area_type_table/natural_grasses.json +++ b/data_descriptors/area_type_table/natural_grasses.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/natural_grasses", + "id": "natural_grasses", "type": "area-type-table", "name": "natural_grasses", "description": "\"Natural grasses\" means grasses growing in areas of low productivity, often situated on rough or uneven ground. This can include rocky areas, briars and heathland." diff --git a/data_descriptors/area_type_table/natural_grasses_of_c3_plant_functional_types.json b/data_descriptors/area_type_table/natural_grasses_of_c3_plant_functional_types.json index a87a9691c..10bace093 100644 --- a/data_descriptors/area_type_table/natural_grasses_of_c3_plant_functional_types.json +++ b/data_descriptors/area_type_table/natural_grasses_of_c3_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/natural_grasses_of_c3_plant_functional_types", + "id": "natural_grasses_of_c3_plant_functional_types", "type": "area-type-table", "name": "natural_grasses_of_c3_plant_functional_types", "description": "\"Natural grasses\" means grasses growing in areas of low productivity, often situated on rough or uneven ground. This can include rocky areas, briars and heathland. A \"c3 plant\" is one that utilizes the C3 carbon fixation pathway as the sole mechanism to bind CO2 before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/natural_grasses_of_c4_plant_functional_types.json b/data_descriptors/area_type_table/natural_grasses_of_c4_plant_functional_types.json index 8a79a2f80..eb45c56bb 100644 --- a/data_descriptors/area_type_table/natural_grasses_of_c4_plant_functional_types.json +++ b/data_descriptors/area_type_table/natural_grasses_of_c4_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/natural_grasses_of_c4_plant_functional_types", + "id": "natural_grasses_of_c4_plant_functional_types", "type": "area-type-table", "name": "natural_grasses_of_c4_plant_functional_types", "description": "\"Natural grasses\" means grasses growing in areas of low productivity, often situated on rough or uneven ground. This can include rocky areas, briars and heathland. A \"c4 plant\" is one that utilizes the C4 carbon fixation pathway in which the CO2 is first bound to a compound containing four carbon atoms before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/pastures.json b/data_descriptors/area_type_table/pastures.json index 3ae7e4217..c2cb28591 100644 --- a/data_descriptors/area_type_table/pastures.json +++ b/data_descriptors/area_type_table/pastures.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/pastures", + "id": "pastures", "type": "area-type-table", "name": "pastures", "description": "Pastures are assumed to be anthropogenic in origin. They include anthropogenically managed pastureland and rangeland." diff --git a/data_descriptors/area_type_table/pastures_of_c3_plant_functional_types.json b/data_descriptors/area_type_table/pastures_of_c3_plant_functional_types.json index b92132565..1a0b588d7 100644 --- a/data_descriptors/area_type_table/pastures_of_c3_plant_functional_types.json +++ b/data_descriptors/area_type_table/pastures_of_c3_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/pastures_of_c3_plant_functional_types", + "id": "pastures_of_c3_plant_functional_types", "type": "area-type-table", "name": "pastures_of_c3_plant_functional_types", "description": "Pastures are assumed to be anthropogenic in origin. They include anthropogenically managed pastureland and rangeland. A \"c3 plant\" is one that utilizes the C3 carbon fixation pathway as the sole mechanism to bind CO2 before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/pastures_of_c4_plant_functional_types.json b/data_descriptors/area_type_table/pastures_of_c4_plant_functional_types.json index 226641d18..8bfa1708b 100644 --- a/data_descriptors/area_type_table/pastures_of_c4_plant_functional_types.json +++ b/data_descriptors/area_type_table/pastures_of_c4_plant_functional_types.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/pastures_of_c4_plant_functional_types", + "id": "pastures_of_c4_plant_functional_types", "type": "area-type-table", "name": "pastures_of_c4_plant_functional_types", "description": "Pastures are assumed to be anthropogenic in origin. They include anthropogenically managed pastureland and rangeland. A \"c4 plant\" is one that utilizes the C4 carbon fixation pathway in which the CO2 is first bound to a compound containing four carbon atoms before photosynthesis reactions take place. All trees are C3 type. Grasses and crops can be C3 or C4." diff --git a/data_descriptors/area_type_table/permafrost.json b/data_descriptors/area_type_table/permafrost.json index 4d5faedb9..7475690ce 100644 --- a/data_descriptors/area_type_table/permafrost.json +++ b/data_descriptors/area_type_table/permafrost.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/permafrost", + "id": "permafrost", "type": "area-type-table", "name": "permafrost", "description": "An area type of \"permafrost\" indicates where soil or rock has remained at a temperature at or below zero degrees Celsius throughout the seasonal cycle for two or more years." diff --git a/data_descriptors/area_type_table/primary_and_secondary_land.json b/data_descriptors/area_type_table/primary_and_secondary_land.json index c834a6742..f52fa223e 100644 --- a/data_descriptors/area_type_table/primary_and_secondary_land.json +++ b/data_descriptors/area_type_table/primary_and_secondary_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/primary_and_secondary_land", + "id": "primary_and_secondary_land", "type": "area-type-table", "name": "primary_and_secondary_land", "description": "\"Primary and secondary land\" is land that is not in use as crop land or pasture land, including forests, grasslands, bare ground and vegetated wetlands. \"Primary land\" is land that has not undergone lulcc (land use or land cover change) due to human disturbance. \"Secondary land\" is land that has previously been used for agriculture, urban development or logging and has subsequently been abandoned. Reference: Hurtt et al. (2011), Climatic Change, 109 - 117, Harmonization of land-use scenarios for the period 1500\u20132100: 600 years of global gridded annual land-use transitions, wood harvest, and resulting secondary lands, doi: 10.1007/s10584-011-0153-2. \"Primary and secondary land\" refers to land use or management, rather than to specific categories of vegetation cover, e.g. the primary and secondary succession of plant species." diff --git a/data_descriptors/area_type_table/primary_deciduous_trees.json b/data_descriptors/area_type_table/primary_deciduous_trees.json index 0c685478f..8c784be0f 100644 --- a/data_descriptors/area_type_table/primary_deciduous_trees.json +++ b/data_descriptors/area_type_table/primary_deciduous_trees.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/primary_deciduous_trees", + "id": "primary_deciduous_trees", "type": "area-type-table", "name": "primary_deciduous_trees", "description": "A primary forest is a naturally regenerated forest of native species, where there are no clearly visible indications of human activities and the ecological processes are not significantly disturbed. Reference: 'Global Forest Resources Assessment: Terms and Definitions', Forestry Department of Food and Agriculture Organization (FAO) of the United Nations, Rome 2010, www.fao.org/forestry/14241-0d7b74f45b0d2cfef31599cc17e4c28cd.pdf. Deciduous trees lose their leaves seasonally, for example, during winter in high latitudes or following seasonal variations in rainfall." diff --git a/data_descriptors/area_type_table/primary_evergreen_trees.json b/data_descriptors/area_type_table/primary_evergreen_trees.json index a06c784c5..c0517504a 100644 --- a/data_descriptors/area_type_table/primary_evergreen_trees.json +++ b/data_descriptors/area_type_table/primary_evergreen_trees.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/primary_evergreen_trees", + "id": "primary_evergreen_trees", "type": "area-type-table", "name": "primary_evergreen_trees", "description": "A primary forest is a naturally regenerated forest of native species, where there are no clearly visible indications of human activities and the ecological processes are not significantly disturbed. Reference: 'Global Forest Resources Assessment: Terms and Definitions', Forestry Department of Food and Agriculture Organization (FAO) of the United Nations, Rome 2010, www.fao.org/forestry/14241-0d7b74f45b0d2cfef31599cc17e4c28cd.pdf. Evergreen trees have leaves in all seasons." diff --git a/data_descriptors/area_type_table/rain.json b/data_descriptors/area_type_table/rain.json index 77489028a..7cdf21bd3 100644 --- a/data_descriptors/area_type_table/rain.json +++ b/data_descriptors/area_type_table/rain.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/rain", + "id": "rain", "type": "area-type-table", "name": "rain", "description": "An area_type of \"rain\" indicates that falling rain is present at some level in the atmospheric column above an area on the surface of the Earth." diff --git a/data_descriptors/area_type_table/sea.json b/data_descriptors/area_type_table/sea.json index 834aa8e2e..08f956b2f 100644 --- a/data_descriptors/area_type_table/sea.json +++ b/data_descriptors/area_type_table/sea.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/sea", + "id": "sea", "type": "area-type-table", "name": "sea", "description": "The area occupied by type \"sea\" is equal to the sum of the areas of types \"ice_free_sea\" and \"sea_ice\"." diff --git a/data_descriptors/area_type_table/sea_ice.json b/data_descriptors/area_type_table/sea_ice.json index 8f97cdde1..204eb32a5 100644 --- a/data_descriptors/area_type_table/sea_ice.json +++ b/data_descriptors/area_type_table/sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/sea_ice", + "id": "sea_ice", "type": "area-type-table", "name": "sea_ice", "description": "The area occupied by type \"sea_ice\" within a grid cell is the sum of the areas of types \"sea_ice_melt_pond\" and \"melt_pond_free_sea_ice\". Melt ponds occur on top of the existing sea ice. The area occupied by type \"sea\" is equal to the sum of the areas of types \"ice_free_sea\" and \"sea_ice\"." diff --git a/data_descriptors/area_type_table/sea_ice_melt_pond.json b/data_descriptors/area_type_table/sea_ice_melt_pond.json index ba23e4e40..dfbf86be1 100644 --- a/data_descriptors/area_type_table/sea_ice_melt_pond.json +++ b/data_descriptors/area_type_table/sea_ice_melt_pond.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/sea_ice_melt_pond", + "id": "sea_ice_melt_pond", "type": "area-type-table", "name": "sea_ice_melt_pond", "description": "The area classified as type \"sea_ice\" within a grid cell is unaltered when an area of type \"sea_ice_melt_pond\" is also present because melt ponds occur on top of the existing sea ice." diff --git a/data_descriptors/area_type_table/sea_ice_ridges.json b/data_descriptors/area_type_table/sea_ice_ridges.json index 254321adc..8cbb4780e 100644 --- a/data_descriptors/area_type_table/sea_ice_ridges.json +++ b/data_descriptors/area_type_table/sea_ice_ridges.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/sea_ice_ridges", + "id": "sea_ice_ridges", "type": "area-type-table", "name": "sea_ice_ridges", "description": "Sea ice \"ridging\" occurs in rough sea conditions. The motion of the sea surface can cause areas of sea ice to deform and fold resulting in ridged upper and lower surfaces. The ridges can be as much as twenty metres thick if thick ice is deformed." diff --git a/data_descriptors/area_type_table/secondary_deciduous_trees.json b/data_descriptors/area_type_table/secondary_deciduous_trees.json index 3559598c7..803f7dd28 100644 --- a/data_descriptors/area_type_table/secondary_deciduous_trees.json +++ b/data_descriptors/area_type_table/secondary_deciduous_trees.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/secondary_deciduous_trees", + "id": "secondary_deciduous_trees", "type": "area-type-table", "name": "secondary_deciduous_trees", "description": "A secondary forest is a forest that has been logged and has recovered naturally or artificially. Reference: 'Report of the ad hoc technical expert group on forest biological diversity', United Nations Convention on Biological Diversity, www.cbd.int/forest/definitions.shtml. Deciduous trees lose their leaves seasonally, for example, during winter in high latitudes or following seasonal variations in rainfall." diff --git a/data_descriptors/area_type_table/secondary_evergreen_trees.json b/data_descriptors/area_type_table/secondary_evergreen_trees.json index 7b03c513a..a5582e1df 100644 --- a/data_descriptors/area_type_table/secondary_evergreen_trees.json +++ b/data_descriptors/area_type_table/secondary_evergreen_trees.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/secondary_evergreen_trees", + "id": "secondary_evergreen_trees", "type": "area-type-table", "name": "secondary_evergreen_trees", "description": "A secondary forest is a forest that has been logged and has recovered naturally or artificially. Reference: 'Report of the ad hoc technical expert group on forest biological diversity', United Nations Convention on Biological Diversity, www.cbd.int/forest/definitions.shtml. Evergreen trees have leaves in all seasons." diff --git a/data_descriptors/area_type_table/shrubs.json b/data_descriptors/area_type_table/shrubs.json index c9083e371..d7ea2ced1 100644 --- a/data_descriptors/area_type_table/shrubs.json +++ b/data_descriptors/area_type_table/shrubs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/shrubs", + "id": "shrubs", "type": "area-type-table", "name": "shrubs", "description": "The distinction between trees and shrubs is model dependent." diff --git a/data_descriptors/area_type_table/smoke.json b/data_descriptors/area_type_table/smoke.json index ed0a60bc8..5aff2c5bb 100644 --- a/data_descriptors/area_type_table/smoke.json +++ b/data_descriptors/area_type_table/smoke.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/smoke", + "id": "smoke", "type": "area-type-table", "name": "smoke", "description": "An area_type of \"smoke\" indicates that smoke aerosol is present at some level in the atmospheric column above an area on the surface of the Earth." diff --git a/data_descriptors/area_type_table/snow.json b/data_descriptors/area_type_table/snow.json index 0bbde9b55..3c1376f12 100644 --- a/data_descriptors/area_type_table/snow.json +++ b/data_descriptors/area_type_table/snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/snow", + "id": "snow", "type": "area-type-table", "name": "snow", "description": null diff --git a/data_descriptors/area_type_table/snow_free_land.json b/data_descriptors/area_type_table/snow_free_land.json index 42891e345..18c396c92 100644 --- a/data_descriptors/area_type_table/snow_free_land.json +++ b/data_descriptors/area_type_table/snow_free_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/snow_free_land", + "id": "snow_free_land", "type": "area-type-table", "name": "snow_free_land", "description": null diff --git a/data_descriptors/area_type_table/stratiform_cloud.json b/data_descriptors/area_type_table/stratiform_cloud.json index 1edc9223b..2bb9c9aa7 100644 --- a/data_descriptors/area_type_table/stratiform_cloud.json +++ b/data_descriptors/area_type_table/stratiform_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/stratiform_cloud", + "id": "stratiform_cloud", "type": "area-type-table", "name": "stratiform_cloud", "description": "This area type complements the \"convective_cloud\" area type, which is the other major category of cloud. The \"cloud\" area type is a more general term and includes both convective_cloud and stratiform_cloud types." diff --git a/data_descriptors/area_type_table/trees.json b/data_descriptors/area_type_table/trees.json index ec23f7067..e9b3e022a 100644 --- a/data_descriptors/area_type_table/trees.json +++ b/data_descriptors/area_type_table/trees.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/trees", + "id": "trees", "type": "area-type-table", "name": "trees", "description": "The distinction between trees and shrubs is model dependent. All trees are C3 plant functional type." diff --git a/data_descriptors/area_type_table/unfrozen_soil.json b/data_descriptors/area_type_table/unfrozen_soil.json index 81bfee27b..7bc374c19 100644 --- a/data_descriptors/area_type_table/unfrozen_soil.json +++ b/data_descriptors/area_type_table/unfrozen_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/unfrozen_soil", + "id": "unfrozen_soil", "type": "area-type-table", "name": "unfrozen_soil", "description": "An area type of \"unfrozen_soil\" means that the soil at the surface is unfrozen. Frozen soil may be present at lower levels within a soil model." diff --git a/data_descriptors/area_type_table/urban.json b/data_descriptors/area_type_table/urban.json index 5a78857cc..c69dcb44c 100644 --- a/data_descriptors/area_type_table/urban.json +++ b/data_descriptors/area_type_table/urban.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/urban", + "id": "urban", "type": "area-type-table", "name": "urban", "description": "Urban land is comprised of areas where much of the land is covered by structures. Included in this category are cities, towns and villages. Reference: Anderson, J.R, E. E. Hardy, J. T. Roach and R. E. Witmer (1976), A Land Use And Land Cover Classification System For Use With Remote Sensor Data, Appendix C Land Use Definitions, Geological Survey Professional Paper 964, A revision of the land use classification system as presented in U.S. Geological Survey Circular 671, https://www.usbr.gov/lc/socal/reports/SMappend_C.pdf." diff --git a/data_descriptors/area_type_table/vegetation.json b/data_descriptors/area_type_table/vegetation.json index d43618579..a2bee7f79 100644 --- a/data_descriptors/area_type_table/vegetation.json +++ b/data_descriptors/area_type_table/vegetation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/vegetation", + "id": "vegetation", "type": "area-type-table", "name": "vegetation", "description": null diff --git a/data_descriptors/area_type_table/volcanic_ash_cloud.json b/data_descriptors/area_type_table/volcanic_ash_cloud.json index adbfb52d4..7dd4da547 100644 --- a/data_descriptors/area_type_table/volcanic_ash_cloud.json +++ b/data_descriptors/area_type_table/volcanic_ash_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/volcanic_ash_cloud", + "id": "volcanic_ash_cloud", "type": "area-type-table", "name": "volcanic_ash_cloud", "description": "An area_type of \"volcanic_ash_cloud\" indicates that volcanic ash aerosol is present at some level in the atmospheric column above an area on the surface of the Earth." diff --git a/data_descriptors/area_type_table/wetland.json b/data_descriptors/area_type_table/wetland.json index e9b02ce88..3ff838764 100644 --- a/data_descriptors/area_type_table/wetland.json +++ b/data_descriptors/area_type_table/wetland.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "cf:area-type-table/wetland", + "id": "wetland", "type": "area-type-table", "name": "wetland", "description": "Wetlands are areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season." diff --git a/data_descriptors/standard_name/acoustic_area_backscattering_strength_in_sea_water.json b/data_descriptors/standard_name/acoustic_area_backscattering_strength_in_sea_water.json index d7ea55e60..bf5886cb9 100644 --- a/data_descriptors/standard_name/acoustic_area_backscattering_strength_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_area_backscattering_strength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_area_backscattering_strength_in_sea_water", + "id": "acoustic_area_backscattering_strength_in_sea_water", "type": "standard_name", "name": "acoustic_area_backscattering_strength_in_sea_water", "description": "Acoustic area backscattering strength is 10 times the log10 of the ratio of the area backscattering coefficient to the reference value, 1 (m2 m-2). Area backscattering coefficient is the integral of the volume backscattering coefficient over a defined distance. Volume backscattering coefficient is the linear form of acoustic_volume_backscattering_strength_in_sea_water. For further details see MacLennan et. al (2002) doi:10.1006/jmsc.2001.1158.", diff --git a/data_descriptors/standard_name/acoustic_centre_of_mass_in_sea_water.json b/data_descriptors/standard_name/acoustic_centre_of_mass_in_sea_water.json index 5276fffbe..644814f22 100644 --- a/data_descriptors/standard_name/acoustic_centre_of_mass_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_centre_of_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_centre_of_mass_in_sea_water", + "id": "acoustic_centre_of_mass_in_sea_water", "type": "standard_name", "name": "acoustic_centre_of_mass_in_sea_water", "description": "Acoustic centre of mass is the average of all sampled depths weighted by their volume backscattering coefficient. Volume backscattering coefficient is the linear form of acoustic_volume_backscattering_strength_in_sea_water. For further details see Urmy et. al (2012) doi:10.1093/icesjms/fsr205.", diff --git a/data_descriptors/standard_name/acoustic_equivalent_area_in_sea_water.json b/data_descriptors/standard_name/acoustic_equivalent_area_in_sea_water.json index a35bee28a..dca22e036 100644 --- a/data_descriptors/standard_name/acoustic_equivalent_area_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_equivalent_area_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_equivalent_area_in_sea_water", + "id": "acoustic_equivalent_area_in_sea_water", "type": "standard_name", "name": "acoustic_equivalent_area_in_sea_water", "description": "Acoustic equivalent area is the squared area backscattering coefficient divided by the depth integral of squared volume backscattering coefficient. Area backscattering coefficient is the integral of the volume backscattering coefficient over a defined distance. Volume backscattering coefficient is the linear form of acoustic_volume_backscattering_strength_in_sea_water. The parameter is computed to provide a value that represents the area that would be occupied if all data cells contained the mean density and is the reciprocal of acoustic_index_of_aggregation_in_sea_water. For further details see Urmy et. al (2012) doi:10.1093/icesjms/fsr205 and Woillez et. al (2007) doi.org/10.1093/icesjms/fsm025.", diff --git a/data_descriptors/standard_name/acoustic_index_of_aggregation_in_sea_water.json b/data_descriptors/standard_name/acoustic_index_of_aggregation_in_sea_water.json index ef5552674..5825637c0 100644 --- a/data_descriptors/standard_name/acoustic_index_of_aggregation_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_index_of_aggregation_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_index_of_aggregation_in_sea_water", + "id": "acoustic_index_of_aggregation_in_sea_water", "type": "standard_name", "name": "acoustic_index_of_aggregation_in_sea_water", "description": "Acoustic index of aggregation is the depth integral of squared volume backscattering coefficient divided by the squared area backscattering coefficient. Volume backscattering coefficient is the linear form of acoustic_volume_backscattering_strength_in_sea_water. Area backscattering coefficient is the integral of the volume backscattering coefficient over a defined distance. The parameter is computed to provide a value that represents the patchiness of biomass in the water column in the field of fisheries acoustics - the value is high when small areas are much denser than the rest of the distribution. The parameter is also the reciprocal of acoustic_equivalent_area_in_sea_water. For further details see Urmy et. al (2012) doi:10.1093/icesjms/fsr205 and Woillez et. al (2007) doi.org/10.1093/icesjms/fsm025.", diff --git a/data_descriptors/standard_name/acoustic_inertia_in_sea_water.json b/data_descriptors/standard_name/acoustic_inertia_in_sea_water.json index 67d6c7fe9..f89b7cd18 100644 --- a/data_descriptors/standard_name/acoustic_inertia_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_inertia_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_inertia_in_sea_water", + "id": "acoustic_inertia_in_sea_water", "type": "standard_name", "name": "acoustic_inertia_in_sea_water", "description": "Acoustic inertia is the sum of squared distances from the acoustic_centre_of_mass weighted by the volume backscattering coefficient at each distance and normalized by the total area backscattering coefficient. Volume backscattering coefficient is the linear form of acoustic_volume_backscattering_strength_in_sea_water. Area backscattering coefficient is the integral of the volume backscattering coefficient over a defined distance. For further details see Urmy et. al (2012) doi:10.1093/icesjms/fsr205 and Bez and Rivoirard (2001) doi:10.1016/S0165-7836(00)00241-1.", diff --git a/data_descriptors/standard_name/acoustic_proportion_occupied_in_sea_water.json b/data_descriptors/standard_name/acoustic_proportion_occupied_in_sea_water.json index ad45d8318..e8aa16f43 100644 --- a/data_descriptors/standard_name/acoustic_proportion_occupied_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_proportion_occupied_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_proportion_occupied_in_sea_water", + "id": "acoustic_proportion_occupied_in_sea_water", "type": "standard_name", "name": "acoustic_proportion_occupied_in_sea_water", "description": "Acoustic proportion occupied is occupied volume divided by the volume sampled. Occupied volume is the integral of the ratio of acoustic_volume_backscattering_strength_in_sea_water above -90 dB to the reference value, 1 m2 m-2. For further details see Urmy et. al (2012) doi:10.1093/icesjms/fsr205.", diff --git a/data_descriptors/standard_name/acoustic_signal_roundtrip_travel_time_in_sea_water.json b/data_descriptors/standard_name/acoustic_signal_roundtrip_travel_time_in_sea_water.json index 2c75e34f9..4cbda511f 100644 --- a/data_descriptors/standard_name/acoustic_signal_roundtrip_travel_time_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_signal_roundtrip_travel_time_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_signal_roundtrip_travel_time_in_sea_water", + "id": "acoustic_signal_roundtrip_travel_time_in_sea_water", "type": "standard_name", "name": "acoustic_signal_roundtrip_travel_time_in_sea_water", "description": "The quantity with standard name acoustic_signal_roundtrip_travel_time_in_sea_water is the time taken for an acoustic signal to propagate from the emitting instrument to a reflecting surface and back again to the instrument. In the case of an instrument based on the sea floor and measuring the roundtrip time to the sea surface, the data are commonly used as a measure of ocean heat content.", diff --git a/data_descriptors/standard_name/acoustic_target_strength_in_sea_water.json b/data_descriptors/standard_name/acoustic_target_strength_in_sea_water.json index 28ddd8095..2cfbd42e2 100644 --- a/data_descriptors/standard_name/acoustic_target_strength_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_target_strength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_target_strength_in_sea_water", + "id": "acoustic_target_strength_in_sea_water", "type": "standard_name", "name": "acoustic_target_strength_in_sea_water", "description": "Target strength is 10 times the log10 of the ratio of backscattering cross-section to the reference value, 1 m2. Backscattering cross-section is a parameter computed from the intensity of the backscattered sound wave relative to the intensity of the incident sound wave. For further details see MacLennan et. al (2002) doi:10.1006/jmsc.2001.1158.", diff --git a/data_descriptors/standard_name/acoustic_volume_backscattering_strength_in_sea_water.json b/data_descriptors/standard_name/acoustic_volume_backscattering_strength_in_sea_water.json index d068ff279..3527d334a 100644 --- a/data_descriptors/standard_name/acoustic_volume_backscattering_strength_in_sea_water.json +++ b/data_descriptors/standard_name/acoustic_volume_backscattering_strength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/acoustic_volume_backscattering_strength_in_sea_water", + "id": "acoustic_volume_backscattering_strength_in_sea_water", "type": "standard_name", "name": "acoustic_volume_backscattering_strength_in_sea_water", "description": "Acoustic volume backscattering strength is 10 times the log10 of the ratio of the volume backscattering coefficient to the reference value, 1 m-1. Volume backscattering coefficient is the integral of the backscattering cross-section divided by the volume sampled. Backscattering cross-section is a parameter computed from the intensity of the backscattered sound wave relative to the intensity of the incident sound wave. The parameter is computed to provide a measurement that is proportional to biomass density per unit volume in the field of fisheries acoustics. For further details see MacLennan et. al (2002) doi:10.1006/jmsc.2001.1158.", diff --git a/data_descriptors/standard_name/aerodynamic_particle_diameter.json b/data_descriptors/standard_name/aerodynamic_particle_diameter.json index 9548a598f..29c0aeca9 100644 --- a/data_descriptors/standard_name/aerodynamic_particle_diameter.json +++ b/data_descriptors/standard_name/aerodynamic_particle_diameter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/aerodynamic_particle_diameter", + "id": "aerodynamic_particle_diameter", "type": "standard_name", "name": "aerodynamic_particle_diameter", "description": "The diameter of a spherical particle with density 1000 kg m-3 having the same aerodynamic properties as the particles in question.", diff --git a/data_descriptors/standard_name/aerodynamic_resistance.json b/data_descriptors/standard_name/aerodynamic_resistance.json index e4f06ddc6..aff539834 100644 --- a/data_descriptors/standard_name/aerodynamic_resistance.json +++ b/data_descriptors/standard_name/aerodynamic_resistance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/aerodynamic_resistance", + "id": "aerodynamic_resistance", "type": "standard_name", "name": "aerodynamic_resistance", "description": "The \"aerodynamic_resistance\" is the resistance to mixing through the boundary layer toward the surface by means of the dominant process, turbulent transport. Reference: Wesely, M. L., 1989, doi:10.1016/0004-6981(89)90153-4.", diff --git a/data_descriptors/standard_name/aerosol_type_in_atmosphere_layer_in_air.json b/data_descriptors/standard_name/aerosol_type_in_atmosphere_layer_in_air.json index 1f9a7eaac..2608ef83e 100644 --- a/data_descriptors/standard_name/aerosol_type_in_atmosphere_layer_in_air.json +++ b/data_descriptors/standard_name/aerosol_type_in_atmosphere_layer_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/aerosol_type_in_atmosphere_layer_in_air", + "id": "aerosol_type_in_atmosphere_layer_in_air", "type": "standard_name", "name": "aerosol_type_in_atmosphere_layer_in_air", "description": "A variable with the standard_name of aerosol_type_in_atmosphere_layer_in_air contains either strings which indicate the type of the aerosol determined following a certain aerosol typing schema, or flags which can be translated to strings using flag_values and flag_meanings attributes. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s).", diff --git a/data_descriptors/standard_name/age_of_sea_ice.json b/data_descriptors/standard_name/age_of_sea_ice.json index 1723ca83f..ee5a18a5b 100644 --- a/data_descriptors/standard_name/age_of_sea_ice.json +++ b/data_descriptors/standard_name/age_of_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/age_of_sea_ice", + "id": "age_of_sea_ice", "type": "standard_name", "name": "age_of_sea_ice", "description": "\"Age of sea ice\" means the length of time elapsed since the ice formed. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/age_of_stratospheric_air.json b/data_descriptors/standard_name/age_of_stratospheric_air.json index 00a99d096..317c856b9 100644 --- a/data_descriptors/standard_name/age_of_stratospheric_air.json +++ b/data_descriptors/standard_name/age_of_stratospheric_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/age_of_stratospheric_air", + "id": "age_of_stratospheric_air", "type": "standard_name", "name": "age_of_stratospheric_air", "description": "\"Age of stratospheric air\" means an estimate of the time since a parcel of stratospheric air was last in contact with the troposphere.", diff --git a/data_descriptors/standard_name/age_of_surface_snow.json b/data_descriptors/standard_name/age_of_surface_snow.json index 6c51c9972..0192c34f8 100644 --- a/data_descriptors/standard_name/age_of_surface_snow.json +++ b/data_descriptors/standard_name/age_of_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/age_of_surface_snow", + "id": "age_of_surface_snow", "type": "standard_name", "name": "age_of_surface_snow", "description": "\"Age of surface snow\" means the length of time elapsed since the snow accumulated on the earth's surface. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/aggregate_quality_flag.json b/data_descriptors/standard_name/aggregate_quality_flag.json index b9ec11b77..0071d65aa 100644 --- a/data_descriptors/standard_name/aggregate_quality_flag.json +++ b/data_descriptors/standard_name/aggregate_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/aggregate_quality_flag", + "id": "aggregate_quality_flag", "type": "standard_name", "name": "aggregate_quality_flag", "description": "This flag is an algorithmic combination of the results of all relevant quality tests run for the related ancillary parent data variable. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. The aggregate quality flag provides a summary of all quality tests performed on the data variable (both automated and manual) whether present in the dataset as independent ancillary variables to the parent data variable or not.", diff --git a/data_descriptors/standard_name/air_density.json b/data_descriptors/standard_name/air_density.json index 452f19152..58615317e 100644 --- a/data_descriptors/standard_name/air_density.json +++ b/data_descriptors/standard_name/air_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_density", + "id": "air_density", "type": "standard_name", "name": "air_density", "description": null, diff --git a/data_descriptors/standard_name/air_equivalent_potential_temperature.json b/data_descriptors/standard_name/air_equivalent_potential_temperature.json index 280ebee23..703208581 100644 --- a/data_descriptors/standard_name/air_equivalent_potential_temperature.json +++ b/data_descriptors/standard_name/air_equivalent_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_equivalent_potential_temperature", + "id": "air_equivalent_potential_temperature", "type": "standard_name", "name": "air_equivalent_potential_temperature", "description": "The \"equivalent potential temperature\" is a thermodynamic quantity, with its natural logarithm proportional to the entropy of moist air, that is conserved in a reversible moist adiabatic process. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Equivalent_potential_temperature. It is the temperature of a parcel of air if all the moisture contained in it were first condensed, releasing latent heat, before moving the parcel dry adiabatically to a standard pressure, typically representative of mean sea level pressure. To specify the standard pressure to which the quantity applies, provide a scalar coordinate variable with standard name reference_pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_equivalent_temperature.json b/data_descriptors/standard_name/air_equivalent_temperature.json index f0dc669d4..bf4ffbfe1 100644 --- a/data_descriptors/standard_name/air_equivalent_temperature.json +++ b/data_descriptors/standard_name/air_equivalent_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_equivalent_temperature", + "id": "air_equivalent_temperature", "type": "standard_name", "name": "air_equivalent_temperature", "description": "The equivalent temperature is the temperature that an air parcel would have if all water vapor were condensed at contstant pressure and the enthalpy released from the vapor used to heat the air. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Equivalent_temperature. It is the isobaric equivalent temperature and not the adiabatic equivalent temperature, also known as pseudoequivalent temperature, which has the standard name air_pseudo_equivalent_temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_potential_temperature.json b/data_descriptors/standard_name/air_potential_temperature.json index 7358767b2..25fd41319 100644 --- a/data_descriptors/standard_name/air_potential_temperature.json +++ b/data_descriptors/standard_name/air_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_potential_temperature", + "id": "air_potential_temperature", "type": "standard_name", "name": "air_potential_temperature", "description": "Air potential temperature is the temperature a parcel of air would have if moved dry adiabatically to a standard pressure, typically representative of mean sea level pressure. To specify the standard pressure to which the quantity applies, provide a scalar coordinate variable with standard name reference_pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_pressure.json b/data_descriptors/standard_name/air_pressure.json index f51202c4d..a6701cd20 100644 --- a/data_descriptors/standard_name/air_pressure.json +++ b/data_descriptors/standard_name/air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure", + "id": "air_pressure", "type": "standard_name", "name": "air_pressure", "description": "Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_anomaly.json b/data_descriptors/standard_name/air_pressure_anomaly.json index ee6cfd043..30cb6441b 100644 --- a/data_descriptors/standard_name/air_pressure_anomaly.json +++ b/data_descriptors/standard_name/air_pressure_anomaly.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_anomaly", + "id": "air_pressure_anomaly", "type": "standard_name", "name": "air_pressure_anomaly", "description": "The term \"anomaly\" means difference from climatology. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_at_cloud_base.json b/data_descriptors/standard_name/air_pressure_at_cloud_base.json index bc293da64..66bd46e41 100644 --- a/data_descriptors/standard_name/air_pressure_at_cloud_base.json +++ b/data_descriptors/standard_name/air_pressure_at_cloud_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_cloud_base", + "id": "air_pressure_at_cloud_base", "type": "standard_name", "name": "air_pressure_at_cloud_base", "description": "The phrase \"cloud_base\" refers to the base of the lowest cloud. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_at_cloud_top.json b/data_descriptors/standard_name/air_pressure_at_cloud_top.json index 577cf6ba0..569f6f988 100644 --- a/data_descriptors/standard_name/air_pressure_at_cloud_top.json +++ b/data_descriptors/standard_name/air_pressure_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_cloud_top", + "id": "air_pressure_at_cloud_top", "type": "standard_name", "name": "air_pressure_at_cloud_top", "description": "The phrase \"cloud_top\" refers to the top of the highest cloud. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_at_convective_cloud_base.json b/data_descriptors/standard_name/air_pressure_at_convective_cloud_base.json index 4810e1dc3..5f60af58e 100644 --- a/data_descriptors/standard_name/air_pressure_at_convective_cloud_base.json +++ b/data_descriptors/standard_name/air_pressure_at_convective_cloud_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_convective_cloud_base", + "id": "air_pressure_at_convective_cloud_base", "type": "standard_name", "name": "air_pressure_at_convective_cloud_base", "description": "The phrase \"cloud_base\" refers to the base of the lowest cloud. Convective cloud is that produced by the convection schemes in an atmosphere model. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_at_convective_cloud_top.json b/data_descriptors/standard_name/air_pressure_at_convective_cloud_top.json index 079e41229..6e2449162 100644 --- a/data_descriptors/standard_name/air_pressure_at_convective_cloud_top.json +++ b/data_descriptors/standard_name/air_pressure_at_convective_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_convective_cloud_top", + "id": "air_pressure_at_convective_cloud_top", "type": "standard_name", "name": "air_pressure_at_convective_cloud_top", "description": "The phrase \"cloud_top\" refers to the top of the highest cloud. Convective cloud is that produced by the convection schemes in an atmosphere model. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_at_freezing_level.json b/data_descriptors/standard_name/air_pressure_at_freezing_level.json index 03529820b..2b93dd609 100644 --- a/data_descriptors/standard_name/air_pressure_at_freezing_level.json +++ b/data_descriptors/standard_name/air_pressure_at_freezing_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_freezing_level", + "id": "air_pressure_at_freezing_level", "type": "standard_name", "name": "air_pressure_at_freezing_level", "description": "Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pressure_at_mean_sea_level.json b/data_descriptors/standard_name/air_pressure_at_mean_sea_level.json index 9471847dc..b6bf609ac 100644 --- a/data_descriptors/standard_name/air_pressure_at_mean_sea_level.json +++ b/data_descriptors/standard_name/air_pressure_at_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_mean_sea_level", + "id": "air_pressure_at_mean_sea_level", "type": "standard_name", "name": "air_pressure_at_mean_sea_level", "description": "Air pressure at sea level is the quantity often abbreviated as MSLP or PMSL. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals.", diff --git a/data_descriptors/standard_name/air_pressure_at_top_of_atmosphere_model.json b/data_descriptors/standard_name/air_pressure_at_top_of_atmosphere_model.json index 2da6f6fc9..cb49a1bac 100644 --- a/data_descriptors/standard_name/air_pressure_at_top_of_atmosphere_model.json +++ b/data_descriptors/standard_name/air_pressure_at_top_of_atmosphere_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pressure_at_top_of_atmosphere_model", + "id": "air_pressure_at_top_of_atmosphere_model", "type": "standard_name", "name": "air_pressure_at_top_of_atmosphere_model", "description": "\"Top of atmosphere model\" means the upper boundary of the top layer of an atmosphere model. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/air_pseudo_equivalent_potential_temperature.json b/data_descriptors/standard_name/air_pseudo_equivalent_potential_temperature.json index 8e2304155..b51ad2b80 100644 --- a/data_descriptors/standard_name/air_pseudo_equivalent_potential_temperature.json +++ b/data_descriptors/standard_name/air_pseudo_equivalent_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pseudo_equivalent_potential_temperature", + "id": "air_pseudo_equivalent_potential_temperature", "type": "standard_name", "name": "air_pseudo_equivalent_potential_temperature", "description": "The pseudoequivalent potential temperature is the temperature a parcel of air would have if it is expanded by a pseudoadiabatic (irreversible moist-adiabatic) process to zero pressure and afterwards compressed by a dry-adiabatic process to a standard pressure, typically representative of mean sea level pressure. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Pseudoequivalent_potential_temperature. A pseudoadiabatic process means that the liquid water that condenses is assumed to be removed as soon as it is formed. Reference: AMS Glossary http:/glossary.ametsoc.org/wiki/Pseudoadiabatic_process. To specify the standard pressure to which the quantity applies, provide a scalar coordinate variable with the standard name reference_pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_pseudo_equivalent_temperature.json b/data_descriptors/standard_name/air_pseudo_equivalent_temperature.json index 1e89181ab..c0a44a8dc 100644 --- a/data_descriptors/standard_name/air_pseudo_equivalent_temperature.json +++ b/data_descriptors/standard_name/air_pseudo_equivalent_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_pseudo_equivalent_temperature", + "id": "air_pseudo_equivalent_temperature", "type": "standard_name", "name": "air_pseudo_equivalent_temperature", "description": "The pseudoequivalent temperature is also known as the adiabatic equivalent temperature. It is the temperature that an air parcel would have after undergoing the following process: dry-adiabatic expansion until saturated; pseudoadiabatic expansion until all moisture is precipitated out; dry-adiabatic compression to the initial pressure. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Equivalent_temperature. This quantity is distinct from the isobaric equivalent temperature, also known as equivalent temperature, which has the standard name air_equivalent_temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_temperature.json b/data_descriptors/standard_name/air_temperature.json index de1dd0d0e..d6edf2bcd 100644 --- a/data_descriptors/standard_name/air_temperature.json +++ b/data_descriptors/standard_name/air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_temperature", + "id": "air_temperature", "type": "standard_name", "name": "air_temperature", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_temperature_anomaly.json b/data_descriptors/standard_name/air_temperature_anomaly.json index d28839a21..292645fd8 100644 --- a/data_descriptors/standard_name/air_temperature_anomaly.json +++ b/data_descriptors/standard_name/air_temperature_anomaly.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_temperature_anomaly", + "id": "air_temperature_anomaly", "type": "standard_name", "name": "air_temperature_anomaly", "description": "The term \"anomaly\" means difference from climatology. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_temperature_at_cloud_top.json b/data_descriptors/standard_name/air_temperature_at_cloud_top.json index a8f0e0f5b..fc51b667a 100644 --- a/data_descriptors/standard_name/air_temperature_at_cloud_top.json +++ b/data_descriptors/standard_name/air_temperature_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_temperature_at_cloud_top", + "id": "air_temperature_at_cloud_top", "type": "standard_name", "name": "air_temperature_at_cloud_top", "description": "cloud_top refers to the top of the highest cloud. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_temperature_at_effective_cloud_top_defined_by_infrared_radiation.json b/data_descriptors/standard_name/air_temperature_at_effective_cloud_top_defined_by_infrared_radiation.json index 5e6cd6f44..9657c7ddd 100644 --- a/data_descriptors/standard_name/air_temperature_at_effective_cloud_top_defined_by_infrared_radiation.json +++ b/data_descriptors/standard_name/air_temperature_at_effective_cloud_top_defined_by_infrared_radiation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_temperature_at_effective_cloud_top_defined_by_infrared_radiation", + "id": "air_temperature_at_effective_cloud_top_defined_by_infrared_radiation", "type": "standard_name", "name": "air_temperature_at_effective_cloud_top_defined_by_infrared_radiation", "description": "The \"effective cloud top defined by infrared radiation\" is (approximately) the geometric height above the surface that is one optical depth at infrared wavelengths (in the region of 11 micrometers) below the cloud top that would be detected by visible and lidar techniques. Reference: Minnis, P. et al 2011 CERES Edition-2 Cloud Property Retrievals Using TRMM VIRS and Terra and Aqua MODIS Data x2014; Part I: Algorithms IEEE Transactions on Geoscience and Remote Sensing, 49(11), 4374-4400. doi: http://dx.doi.org/10.1109/TGRS.2011.2144601. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_temperature_lapse_rate.json b/data_descriptors/standard_name/air_temperature_lapse_rate.json index 23427c56c..ac2750c6d 100644 --- a/data_descriptors/standard_name/air_temperature_lapse_rate.json +++ b/data_descriptors/standard_name/air_temperature_lapse_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_temperature_lapse_rate", + "id": "air_temperature_lapse_rate", "type": "standard_name", "name": "air_temperature_lapse_rate", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A lapse rate is the negative derivative of a quantity with respect to increasing height above the surface, or the (positive) derivative with respect to increasing depth. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/air_temperature_threshold.json b/data_descriptors/standard_name/air_temperature_threshold.json index 796dbec35..b863a144b 100644 --- a/data_descriptors/standard_name/air_temperature_threshold.json +++ b/data_descriptors/standard_name/air_temperature_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/air_temperature_threshold", + "id": "air_temperature_threshold", "type": "standard_name", "name": "air_temperature_threshold", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. Air temperature excess and deficit are calculated relative to the air temperature threshold. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: on-scale\", meaning that the temperature is relative to the origin of the scale indicated by the units, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/altimeter_range.json b/data_descriptors/standard_name/altimeter_range.json index 8bf62cf29..6248e7b36 100644 --- a/data_descriptors/standard_name/altimeter_range.json +++ b/data_descriptors/standard_name/altimeter_range.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altimeter_range", + "id": "altimeter_range", "type": "standard_name", "name": "altimeter_range", "description": "An altimeter operates by sending out a short pulse of radiation and measuring the time required for the pulse to return from the sea surface; this measurement is used to calculate the distance between the instrument and the sea surface. That measurement is called the \"altimeter range\" and does not include any range corrections.", diff --git a/data_descriptors/standard_name/altimeter_range_correction_due_to_dry_troposphere.json b/data_descriptors/standard_name/altimeter_range_correction_due_to_dry_troposphere.json index f1b33f749..739f8c70f 100644 --- a/data_descriptors/standard_name/altimeter_range_correction_due_to_dry_troposphere.json +++ b/data_descriptors/standard_name/altimeter_range_correction_due_to_dry_troposphere.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altimeter_range_correction_due_to_dry_troposphere", + "id": "altimeter_range_correction_due_to_dry_troposphere", "type": "standard_name", "name": "altimeter_range_correction_due_to_dry_troposphere", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. To apply the altimeter range correction it must be added to the quantity with standard name altimeter_range. \"Correction_due_to_dry_troposphere\" means a correction for dry gases in the troposphere, i.e. excluding the effect of liquid water. Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_ionosphere, sea_surface_height_correction_due_to_air_pressure_at_low_frequency and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.", diff --git a/data_descriptors/standard_name/altimeter_range_correction_due_to_ionosphere.json b/data_descriptors/standard_name/altimeter_range_correction_due_to_ionosphere.json index 3f64244c3..6f3497aec 100644 --- a/data_descriptors/standard_name/altimeter_range_correction_due_to_ionosphere.json +++ b/data_descriptors/standard_name/altimeter_range_correction_due_to_ionosphere.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altimeter_range_correction_due_to_ionosphere", + "id": "altimeter_range_correction_due_to_ionosphere", "type": "standard_name", "name": "altimeter_range_correction_due_to_ionosphere", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. To apply the altimeter range correction it must be added to the quantity with standard name altimeter_range. \"Correction_due_to_ionosphere\" means a correction for the atmosphere's electron content in the ionosphere. Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_dry_troposphere, sea_surface_height_correction_due_to_air_pressure_at_low_frequency and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.", diff --git a/data_descriptors/standard_name/altimeter_range_correction_due_to_wet_troposphere.json b/data_descriptors/standard_name/altimeter_range_correction_due_to_wet_troposphere.json index 85efbdd2e..114edb04a 100644 --- a/data_descriptors/standard_name/altimeter_range_correction_due_to_wet_troposphere.json +++ b/data_descriptors/standard_name/altimeter_range_correction_due_to_wet_troposphere.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altimeter_range_correction_due_to_wet_troposphere", + "id": "altimeter_range_correction_due_to_wet_troposphere", "type": "standard_name", "name": "altimeter_range_correction_due_to_wet_troposphere", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. To apply the altimeter range correction it must be added to the quantity with standard name altimeter_range. \"Correction_due_to_wet_troposphere\" means a correction for the effect of liquid water in the troposphere. Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_dry_troposphere, altimeter_range_correction_due_to_ionosphere, sea_surface_height_correction_due_to_air_pressure_at_low_frequency and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.", diff --git a/data_descriptors/standard_name/altitude.json b/data_descriptors/standard_name/altitude.json index dbc9e99ca..d18e51b17 100644 --- a/data_descriptors/standard_name/altitude.json +++ b/data_descriptors/standard_name/altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altitude", + "id": "altitude", "type": "standard_name", "name": "altitude", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json b/data_descriptors/standard_name/altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json index 429c09815..9692bec21 100644 --- a/data_descriptors/standard_name/altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json +++ b/data_descriptors/standard_name/altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument", + "id": "altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument", "type": "standard_name", "name": "altitude_at_top_of_atmosphere_boundary_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument", "description": "The altitude at top of atmosphere boundary layer is the elevation above sea level of the top of the (atmosphere) planetary boundary layer. The phrase \"defined_by\" provides the information of the tracer used for identifying the atmospheric boundary layer top. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"By ranging instrument\" means that the backscattering is obtained through ranging techniques like lidar and radar.", diff --git a/data_descriptors/standard_name/altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json b/data_descriptors/standard_name/altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json index d60ce8981..4687ad0b8 100644 --- a/data_descriptors/standard_name/altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json +++ b/data_descriptors/standard_name/altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument", + "id": "altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument", "type": "standard_name", "name": "altitude_at_top_of_atmosphere_mixed_layer_defined_by_ambient_aerosol_particles_backwards_scattering_by_ranging_instrument", "description": "The altitude at top of atmosphere mixed layer is the elevation above sea level of the top of the (atmosphere) mixed layer or convective boundary layer. The phrase \"defined_by\" provides the information of the tracer used for identifying the atmospheric boundary layer top. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"By ranging instrument\" means that the volume backscattering coefficient is obtained through ranging techniques like lidar and radar.", diff --git a/data_descriptors/standard_name/altitude_at_top_of_atmosphere_model.json b/data_descriptors/standard_name/altitude_at_top_of_atmosphere_model.json index ca5be3050..6715d1544 100644 --- a/data_descriptors/standard_name/altitude_at_top_of_atmosphere_model.json +++ b/data_descriptors/standard_name/altitude_at_top_of_atmosphere_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altitude_at_top_of_atmosphere_model", + "id": "altitude_at_top_of_atmosphere_model", "type": "standard_name", "name": "altitude_at_top_of_atmosphere_model", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. \"Top of atmosphere model\" means the upper boundary of the top layer of an atmosphere model.", diff --git a/data_descriptors/standard_name/altitude_at_top_of_dry_convection.json b/data_descriptors/standard_name/altitude_at_top_of_dry_convection.json index 4c0b9cecc..eeb35b2b9 100644 --- a/data_descriptors/standard_name/altitude_at_top_of_dry_convection.json +++ b/data_descriptors/standard_name/altitude_at_top_of_dry_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/altitude_at_top_of_dry_convection", + "id": "altitude_at_top_of_dry_convection", "type": "standard_name", "name": "altitude_at_top_of_dry_convection", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/amplitude_of_global_average_sea_level_change.json b/data_descriptors/standard_name/amplitude_of_global_average_sea_level_change.json index 876a93177..980759f07 100644 --- a/data_descriptors/standard_name/amplitude_of_global_average_sea_level_change.json +++ b/data_descriptors/standard_name/amplitude_of_global_average_sea_level_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/amplitude_of_global_average_sea_level_change", + "id": "amplitude_of_global_average_sea_level_change", "type": "standard_name", "name": "amplitude_of_global_average_sea_level_change", "description": "Global average sea level change is due to change in volume of the water in the ocean, caused by mass and/or density change, or to change in the volume of the ocean basins, caused by tectonics etc. It is sometimes called \"eustatic\", which is a term that also has other definitions. It differs from the change in the global average sea surface height relative to the centre of the Earth by the global average vertical movement of the ocean floor. Zero sea level change is an arbitrary level. Amplitude is the magnitude of a wave modelled by a sinusoidal function. A coordinate variable of harmonic_period should be used to specify the period of the sinusoidal wave. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level.", diff --git a/data_descriptors/standard_name/angle_of_emergence.json b/data_descriptors/standard_name/angle_of_emergence.json index de75d1cc2..b12970284 100644 --- a/data_descriptors/standard_name/angle_of_emergence.json +++ b/data_descriptors/standard_name/angle_of_emergence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angle_of_emergence", + "id": "angle_of_emergence", "type": "standard_name", "name": "angle_of_emergence", "description": "The angle of emergence is that between the direction of a beam of radiation emerging from the surface of a medium and the normal to that surface.", diff --git a/data_descriptors/standard_name/angle_of_incidence.json b/data_descriptors/standard_name/angle_of_incidence.json index 52cab2d12..599ffdd2f 100644 --- a/data_descriptors/standard_name/angle_of_incidence.json +++ b/data_descriptors/standard_name/angle_of_incidence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angle_of_incidence", + "id": "angle_of_incidence", "type": "standard_name", "name": "angle_of_incidence", "description": "The angle of incidence is that between the direction of approach of a beam of radiation toward a surface and the normal to that surface.", diff --git a/data_descriptors/standard_name/angle_of_rotation_from_east_to_x.json b/data_descriptors/standard_name/angle_of_rotation_from_east_to_x.json index dcd19a763..34533f021 100644 --- a/data_descriptors/standard_name/angle_of_rotation_from_east_to_x.json +++ b/data_descriptors/standard_name/angle_of_rotation_from_east_to_x.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angle_of_rotation_from_east_to_x", + "id": "angle_of_rotation_from_east_to_x", "type": "standard_name", "name": "angle_of_rotation_from_east_to_x", "description": "The quantity with standard name angle_of_rotation_from_east_to_x is the angle, anticlockwise reckoned positive, between due East and (dr/di)jk, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It could be used for rotating vector fields between model space and latitude-longitude space.", diff --git a/data_descriptors/standard_name/angle_of_rotation_from_east_to_y.json b/data_descriptors/standard_name/angle_of_rotation_from_east_to_y.json index cbddaed99..66e315d8e 100644 --- a/data_descriptors/standard_name/angle_of_rotation_from_east_to_y.json +++ b/data_descriptors/standard_name/angle_of_rotation_from_east_to_y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angle_of_rotation_from_east_to_y", + "id": "angle_of_rotation_from_east_to_y", "type": "standard_name", "name": "angle_of_rotation_from_east_to_y", "description": "The quantity with standard name angle_of_rotation_from_east_to_y is the angle, anticlockwise reckoned positive, between due East and (dr/dj)ik, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It could be used for rotating vector fields between model space and latitude-longitude space.", diff --git a/data_descriptors/standard_name/angle_of_rotation_from_solar_azimuth_to_platform_azimuth.json b/data_descriptors/standard_name/angle_of_rotation_from_solar_azimuth_to_platform_azimuth.json index 6d9e7d43c..f29842c29 100644 --- a/data_descriptors/standard_name/angle_of_rotation_from_solar_azimuth_to_platform_azimuth.json +++ b/data_descriptors/standard_name/angle_of_rotation_from_solar_azimuth_to_platform_azimuth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angle_of_rotation_from_solar_azimuth_to_platform_azimuth", + "id": "angle_of_rotation_from_solar_azimuth_to_platform_azimuth", "type": "standard_name", "name": "angle_of_rotation_from_solar_azimuth_to_platform_azimuth", "description": "An angle of rotation is reckoned positive in the anticlockwise direction. The \"angle_of_rotation_from_solar_azimuth_to_platform_azimuth\" is the angle of rotation between the solar azimuth angle and the platform azimuth angle. Solar azimuth angle is the horizontal angle between the line of sight from the observation point to the sun and a reference direction at the observation point, which is often due north. The angle is measured clockwise, starting from the reference direction. Platform azimuth angle is the horizontal angle between the line of sight from the observation point to the platform and a reference direction at the observation point, which is often due north. The angle is measured clockwise, starting from the reference direction. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/angstrom_exponent_of_ambient_aerosol_in_air.json b/data_descriptors/standard_name/angstrom_exponent_of_ambient_aerosol_in_air.json index d95bc8b04..aaff2d598 100644 --- a/data_descriptors/standard_name/angstrom_exponent_of_ambient_aerosol_in_air.json +++ b/data_descriptors/standard_name/angstrom_exponent_of_ambient_aerosol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angstrom_exponent_of_ambient_aerosol_in_air", + "id": "angstrom_exponent_of_ambient_aerosol_in_air", "type": "standard_name", "name": "angstrom_exponent_of_ambient_aerosol_in_air", "description": "The \"Angstrom exponent\" appears in the formula relating aerosol optical thickness to the wavelength of incident radiation: T(lambda) = T(lambda0) * [lambda/lambda0] ** (-1 * alpha) where alpha is the Angstrom exponent, lambda is the wavelength of incident radiation, lambda0 is a reference wavelength, T(lambda) and T(lambda0) are the values of aerosol optical thickness at wavelengths lambda and lambda0, respectively. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles.json index 68df85feb..26e8802a3 100644 --- a/data_descriptors/standard_name/angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles", + "id": "angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "angstrom_exponent_of_volume_backwards_scattering_in_air_due_to_ambient_aerosol_particles", "description": "The Angstrom exponent of volume backwards scattering is the Angstrom exponent related only to the aerosol backwards scattering component. It is alpha in the following equation relating volume backwards scattering (back) at the wavelength lambda to volume backwards scattering at a different wavelength lambda0: back(lambda) = back(lambda0) * [lambda/lambda0] ** (-1 * alpha). \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/apparent_air_temperature.json b/data_descriptors/standard_name/apparent_air_temperature.json index 3eac2c3eb..7bd2b831d 100644 --- a/data_descriptors/standard_name/apparent_air_temperature.json +++ b/data_descriptors/standard_name/apparent_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/apparent_air_temperature", + "id": "apparent_air_temperature", "type": "standard_name", "name": "apparent_air_temperature", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The quantity with standard name apparent_air_temperature is the perceived air temperature derived from either a combination of temperature and wind (which has standard name wind_chill_of_air_temperature) or temperature and humidity (which has standard name heat_index_of_air_temperature) for the hour indicated by the time coordinate variable. When the air temperature falls to 283.15 K or below, wind chill is used for the apparent_air_temperature. When the air temperature rises above 299.817 K, the heat index is used for apparent_air_temperature. For temperatures above 283.15 and below 299.817K, the apparent_air_temperature is the ambient air temperature (which has standard name air_temperature). References: https://digital.weather.gov/staticpages/definitions.php; WMO codes registry entry http://codes.wmo.int/grib2/codeflag/4.2/_0-0-21. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/apparent_oxygen_utilization.json b/data_descriptors/standard_name/apparent_oxygen_utilization.json index def4d4a13..0d2098ec6 100644 --- a/data_descriptors/standard_name/apparent_oxygen_utilization.json +++ b/data_descriptors/standard_name/apparent_oxygen_utilization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/apparent_oxygen_utilization", + "id": "apparent_oxygen_utilization", "type": "standard_name", "name": "apparent_oxygen_utilization", "description": "Apparent Oxygen Utilization (AOU) is the difference between measured dissolved oxygen concentration in water, and the equilibrium saturation concentration of dissolved oxygen in water with the same physical and chemical properties. Reference: Broecker, W. S. and T. H. Peng (1982), Tracers in the Sea, Lamont-Doherty Earth Observatory, Palisades, N. Y.", diff --git a/data_descriptors/standard_name/area_fraction.json b/data_descriptors/standard_name/area_fraction.json index 8c7341683..799254e29 100644 --- a/data_descriptors/standard_name/area_fraction.json +++ b/data_descriptors/standard_name/area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/area_fraction", + "id": "area_fraction", "type": "standard_name", "name": "area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. To specify which area is quantified by a variable with standard name area_fraction, provide a coordinate variable or scalar coordinate variable with standard name area_type. Alternatively, if one is defined, use a more specific standard name of X_area_fraction for the fraction of horizontal area occupied by X.", diff --git a/data_descriptors/standard_name/area_fraction_below_surface.json b/data_descriptors/standard_name/area_fraction_below_surface.json index 70761c35f..d0c248303 100644 --- a/data_descriptors/standard_name/area_fraction_below_surface.json +++ b/data_descriptors/standard_name/area_fraction_below_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/area_fraction_below_surface", + "id": "area_fraction_below_surface", "type": "standard_name", "name": "area_fraction_below_surface", "description": "The quantity with standard name area_fraction_below_surface is the fraction of horizontal area where a given isobaric surface is below the (ground or sea) surface. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/area_fraction_of_day_defined_by_solar_zenith_angle.json b/data_descriptors/standard_name/area_fraction_of_day_defined_by_solar_zenith_angle.json index 31a9de7b7..18829e469 100644 --- a/data_descriptors/standard_name/area_fraction_of_day_defined_by_solar_zenith_angle.json +++ b/data_descriptors/standard_name/area_fraction_of_day_defined_by_solar_zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/area_fraction_of_day_defined_by_solar_zenith_angle", + "id": "area_fraction_of_day_defined_by_solar_zenith_angle", "type": "standard_name", "name": "area_fraction_of_day_defined_by_solar_zenith_angle", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. A coordinate variable of solar_zenith_angle indicating the day extent should be specified. Solar zenith angle is the the angle between the line of sight to the sun and the local vertical.", diff --git a/data_descriptors/standard_name/area_fraction_of_night_defined_by_solar_zenith_angle.json b/data_descriptors/standard_name/area_fraction_of_night_defined_by_solar_zenith_angle.json index 1db5da61b..199167222 100644 --- a/data_descriptors/standard_name/area_fraction_of_night_defined_by_solar_zenith_angle.json +++ b/data_descriptors/standard_name/area_fraction_of_night_defined_by_solar_zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/area_fraction_of_night_defined_by_solar_zenith_angle", + "id": "area_fraction_of_night_defined_by_solar_zenith_angle", "type": "standard_name", "name": "area_fraction_of_night_defined_by_solar_zenith_angle", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. A coordinate variable of solar_zenith_angle indicating the day extent should be specified. Solar zenith angle is the the angle between the line of sight to the sun and the local vertical.", diff --git a/data_descriptors/standard_name/area_fraction_of_twilight_defined_by_solar_zenith_angle.json b/data_descriptors/standard_name/area_fraction_of_twilight_defined_by_solar_zenith_angle.json index 631c5676d..0ade2b0de 100644 --- a/data_descriptors/standard_name/area_fraction_of_twilight_defined_by_solar_zenith_angle.json +++ b/data_descriptors/standard_name/area_fraction_of_twilight_defined_by_solar_zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/area_fraction_of_twilight_defined_by_solar_zenith_angle", + "id": "area_fraction_of_twilight_defined_by_solar_zenith_angle", "type": "standard_name", "name": "area_fraction_of_twilight_defined_by_solar_zenith_angle", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. A coordinate variable of solar_zenith_angle indicating the day extent should be specified. Solar zenith angle is the the angle between the line of sight to the sun and the local vertical.", diff --git a/data_descriptors/standard_name/area_type.json b/data_descriptors/standard_name/area_type.json index f364788c5..5d08ff9e6 100644 --- a/data_descriptors/standard_name/area_type.json +++ b/data_descriptors/standard_name/area_type.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/area_type", + "id": "area_type", "type": "standard_name", "name": "area_type", "description": "A variable with the standard_name of area_type contains either strings which indicate the nature of the surface e.g. land, sea, sea_ice, or flags which can be translated to strings using flag_values and flag_meanings attributes. These strings are standardised. Values must be taken from the area_type table.", diff --git a/data_descriptors/standard_name/asymmetry_factor_of_ambient_aerosol_particles.json b/data_descriptors/standard_name/asymmetry_factor_of_ambient_aerosol_particles.json index d87f15f7a..f45afc743 100644 --- a/data_descriptors/standard_name/asymmetry_factor_of_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/asymmetry_factor_of_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/asymmetry_factor_of_ambient_aerosol_particles", + "id": "asymmetry_factor_of_ambient_aerosol_particles", "type": "standard_name", "name": "asymmetry_factor_of_ambient_aerosol_particles", "description": "The asymmetry factor is the angular integral of the aerosol scattering phase function weighted by the cosine of the angle with the incident radiation flux. The asymmetry coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles.json index a5fc4695e..c70803071 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles", + "id": "atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol.json index a5b3f23a7..b6a785ff5 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol", + "id": "atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_black_carbon_ambient_aerosol", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the suspended liquid or solid particles in air (except cloud droplets). \"Ambient aerosol\" is aerosol that has taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles.json index 4a9cb5c52..c7a879a54 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles", + "id": "atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_dust_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json index b3258f4bf..ee68e2697 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles", + "id": "atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_nitrate_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json index 7bad64a7b..05eb8e991 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", + "id": "atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json index 502602c3c..a98ac6f4e 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", + "id": "atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json index 3c67bc59c..3ab8d08f3 100644 --- a/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles", + "id": "atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_absorption_optical_thickness_due_to_sulfate_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Absorption optical thickness\" means that part of the atmosphere optical thickness that is caused by the absorption of incident radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_boundary_layer_thickness.json b/data_descriptors/standard_name/atmosphere_boundary_layer_thickness.json index 496463edc..5d8acac0d 100644 --- a/data_descriptors/standard_name/atmosphere_boundary_layer_thickness.json +++ b/data_descriptors/standard_name/atmosphere_boundary_layer_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_boundary_layer_thickness", + "id": "atmosphere_boundary_layer_thickness", "type": "standard_name", "name": "atmosphere_boundary_layer_thickness", "description": "The atmosphere boundary layer thickness is the \"depth\" or \"height\" of the (atmosphere) planetary boundary layer.", diff --git a/data_descriptors/standard_name/atmosphere_convective_available_potential_energy.json b/data_descriptors/standard_name/atmosphere_convective_available_potential_energy.json index 72bce1ded..ff9e3abec 100644 --- a/data_descriptors/standard_name/atmosphere_convective_available_potential_energy.json +++ b/data_descriptors/standard_name/atmosphere_convective_available_potential_energy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_convective_available_potential_energy", + "id": "atmosphere_convective_available_potential_energy", "type": "standard_name", "name": "atmosphere_convective_available_potential_energy", "description": "Convective(ly) available potential energy (often abbreviated CAPE) is a stability measure calculated by integrating the positive temperature difference between the surrounding atmosphere and a parcel of air lifted adiabatically from a given starting height to its equilibrium level. A coordinate variable of original_air_pressure_of_lifted_parcel should be specified to indicate the starting height of the lifted parcel. CAPE exists under conditions of potential instability, and measures the potential energy per unit mass that would be released by the unstable parcel if it were able to convect upwards to equilibrium.", diff --git a/data_descriptors/standard_name/atmosphere_convective_available_potential_energy_wrt_surface.json b/data_descriptors/standard_name/atmosphere_convective_available_potential_energy_wrt_surface.json index 85f716cdd..e4aff29c0 100644 --- a/data_descriptors/standard_name/atmosphere_convective_available_potential_energy_wrt_surface.json +++ b/data_descriptors/standard_name/atmosphere_convective_available_potential_energy_wrt_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_convective_available_potential_energy_wrt_surface", + "id": "atmosphere_convective_available_potential_energy_wrt_surface", "type": "standard_name", "name": "atmosphere_convective_available_potential_energy_wrt_surface", "description": "Convective(ly) available potential energy (often abbreviated CAPE) is a stability measure calculated by integrating the positive temperature difference between the surrounding atmosphere and a parcel of air lifted adiabatically from the surface to its equilibrium level. CAPE exists under conditions of potential instability, and measures the potential energy per unit mass that would be released by the unstable parcel if it were able to convect upwards to equilibrium.", diff --git a/data_descriptors/standard_name/atmosphere_convective_inhibition.json b/data_descriptors/standard_name/atmosphere_convective_inhibition.json index 9fc0f19a0..eb268d6a8 100644 --- a/data_descriptors/standard_name/atmosphere_convective_inhibition.json +++ b/data_descriptors/standard_name/atmosphere_convective_inhibition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_convective_inhibition", + "id": "atmosphere_convective_inhibition", "type": "standard_name", "name": "atmosphere_convective_inhibition", "description": "Convective inhibition is the amount of energy per unit mass required to overcome the negatively buoyant energy exerted by the environment on a parcel of air. Convective inhibition is often abbreviated as \"CIN\" or \"CINH\". It is calculated by integrating the negative temperature difference between the surrounding atmosphere and a parcel of air lifted adiabatically from a given starting height to its equilibrium level. A coordinate variable of original_air_pressure_of_lifted_parcel should be specified to indicate the starting height of the lifted parcel.", diff --git a/data_descriptors/standard_name/atmosphere_convective_inhibition_wrt_surface.json b/data_descriptors/standard_name/atmosphere_convective_inhibition_wrt_surface.json index 36231c69d..580183de3 100644 --- a/data_descriptors/standard_name/atmosphere_convective_inhibition_wrt_surface.json +++ b/data_descriptors/standard_name/atmosphere_convective_inhibition_wrt_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_convective_inhibition_wrt_surface", + "id": "atmosphere_convective_inhibition_wrt_surface", "type": "standard_name", "name": "atmosphere_convective_inhibition_wrt_surface", "description": "Convective inhibition is the amount of energy per unit mass required to overcome the negatively buoyant energy exerted by the environment on a parcel of air. Convective inhibition is often abbreviated as \"CIN\" or \"CINH\". It is calculated by integrating the negative temperature difference between the surrounding atmosphere and a parcel of air lifted adiabatically from the surface to its equilibrium level.", diff --git a/data_descriptors/standard_name/atmosphere_downdraft_convective_mass_flux.json b/data_descriptors/standard_name/atmosphere_downdraft_convective_mass_flux.json index 0ce7b6386..101bfb824 100644 --- a/data_descriptors/standard_name/atmosphere_downdraft_convective_mass_flux.json +++ b/data_descriptors/standard_name/atmosphere_downdraft_convective_mass_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_downdraft_convective_mass_flux", + "id": "atmosphere_downdraft_convective_mass_flux", "type": "standard_name", "name": "atmosphere_downdraft_convective_mass_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The atmosphere convective mass flux is the vertical transport of mass for a field of cumulus clouds or thermals, given by the product of air density and vertical velocity. For an area-average, cell_methods should specify whether the average is over all the area or the area of updrafts and/or downdrafts only. \"Downdraft\" means that the flux is positive in the downward direction (negative upward).", diff --git a/data_descriptors/standard_name/atmosphere_dry_energy_content.json b/data_descriptors/standard_name/atmosphere_dry_energy_content.json index 6b4f4dd78..885996dba 100644 --- a/data_descriptors/standard_name/atmosphere_dry_energy_content.json +++ b/data_descriptors/standard_name/atmosphere_dry_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_dry_energy_content", + "id": "atmosphere_dry_energy_content", "type": "standard_name", "name": "atmosphere_dry_energy_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/atmosphere_dry_static_energy_content.json b/data_descriptors/standard_name/atmosphere_dry_static_energy_content.json index 5b6a90d9f..5dfbb4d2d 100644 --- a/data_descriptors/standard_name/atmosphere_dry_static_energy_content.json +++ b/data_descriptors/standard_name/atmosphere_dry_static_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_dry_static_energy_content", + "id": "atmosphere_dry_static_energy_content", "type": "standard_name", "name": "atmosphere_dry_static_energy_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/atmosphere_eastward_stress_due_to_gravity_wave_drag.json b/data_descriptors/standard_name/atmosphere_eastward_stress_due_to_gravity_wave_drag.json index b863881f1..58ac8c89f 100644 --- a/data_descriptors/standard_name/atmosphere_eastward_stress_due_to_gravity_wave_drag.json +++ b/data_descriptors/standard_name/atmosphere_eastward_stress_due_to_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_eastward_stress_due_to_gravity_wave_drag", + "id": "atmosphere_eastward_stress_due_to_gravity_wave_drag", "type": "standard_name", "name": "atmosphere_eastward_stress_due_to_gravity_wave_drag", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Atmosphere_Xward_stress is a stress which tends to accelerate the atmosphere in direction X.", diff --git a/data_descriptors/standard_name/atmosphere_energy_content.json b/data_descriptors/standard_name/atmosphere_energy_content.json index b0a3c4949..29b58b4bc 100644 --- a/data_descriptors/standard_name/atmosphere_energy_content.json +++ b/data_descriptors/standard_name/atmosphere_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_energy_content", + "id": "atmosphere_energy_content", "type": "standard_name", "name": "atmosphere_energy_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Atmosphere energy content\" has not yet been precisely defined! Please express your views on this quantity on the CF email list.", diff --git a/data_descriptors/standard_name/atmosphere_enthalpy_content.json b/data_descriptors/standard_name/atmosphere_enthalpy_content.json index 263016fb5..568997bcf 100644 --- a/data_descriptors/standard_name/atmosphere_enthalpy_content.json +++ b/data_descriptors/standard_name/atmosphere_enthalpy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_enthalpy_content", + "id": "atmosphere_enthalpy_content", "type": "standard_name", "name": "atmosphere_enthalpy_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/atmosphere_heat_diffusivity.json b/data_descriptors/standard_name/atmosphere_heat_diffusivity.json index 2aae52b2a..7351fca67 100644 --- a/data_descriptors/standard_name/atmosphere_heat_diffusivity.json +++ b/data_descriptors/standard_name/atmosphere_heat_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_heat_diffusivity", + "id": "atmosphere_heat_diffusivity", "type": "standard_name", "name": "atmosphere_heat_diffusivity", "description": null, diff --git a/data_descriptors/standard_name/atmosphere_helicity.json b/data_descriptors/standard_name/atmosphere_helicity.json index 27fbb331a..4a9bf4d0f 100644 --- a/data_descriptors/standard_name/atmosphere_helicity.json +++ b/data_descriptors/standard_name/atmosphere_helicity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_helicity", + "id": "atmosphere_helicity", "type": "standard_name", "name": "atmosphere_helicity", "description": "One-half the scalar product of the air velocity and vorticity vectors, where vorticity refers to the standard name atmosphere_upward_absolute_vorticity. Helicity is proportional to the strength of the flow, the amount of vertical wind shear, and the amount of turning in the flow.", diff --git a/data_descriptors/standard_name/atmosphere_horizontal_streamfunction.json b/data_descriptors/standard_name/atmosphere_horizontal_streamfunction.json index b011f7b64..79acebdc9 100644 --- a/data_descriptors/standard_name/atmosphere_horizontal_streamfunction.json +++ b/data_descriptors/standard_name/atmosphere_horizontal_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_horizontal_streamfunction", + "id": "atmosphere_horizontal_streamfunction", "type": "standard_name", "name": "atmosphere_horizontal_streamfunction", "description": "\"Horizontal\" indicates that the streamfunction applies to a horizontal velocity field on a particular vertical level.", diff --git a/data_descriptors/standard_name/atmosphere_horizontal_velocity_potential.json b/data_descriptors/standard_name/atmosphere_horizontal_velocity_potential.json index 9e9a44187..3f0233f1f 100644 --- a/data_descriptors/standard_name/atmosphere_horizontal_velocity_potential.json +++ b/data_descriptors/standard_name/atmosphere_horizontal_velocity_potential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_horizontal_velocity_potential", + "id": "atmosphere_horizontal_velocity_potential", "type": "standard_name", "name": "atmosphere_horizontal_velocity_potential", "description": "A velocity is a vector quantity. \"Horizontal\" indicates that the velocity potential applies to a horizontal velocity field on a particular vertical level.", diff --git a/data_descriptors/standard_name/atmosphere_hybrid_height_coordinate.json b/data_descriptors/standard_name/atmosphere_hybrid_height_coordinate.json index 9dd4c60f9..b93f4acec 100644 --- a/data_descriptors/standard_name/atmosphere_hybrid_height_coordinate.json +++ b/data_descriptors/standard_name/atmosphere_hybrid_height_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_hybrid_height_coordinate", + "id": "atmosphere_hybrid_height_coordinate", "type": "standard_name", "name": "atmosphere_hybrid_height_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/atmosphere_hybrid_sigma_pressure_coordinate.json b/data_descriptors/standard_name/atmosphere_hybrid_sigma_pressure_coordinate.json index 370f5047b..37bd0dddb 100644 --- a/data_descriptors/standard_name/atmosphere_hybrid_sigma_pressure_coordinate.json +++ b/data_descriptors/standard_name/atmosphere_hybrid_sigma_pressure_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_hybrid_sigma_pressure_coordinate", + "id": "atmosphere_hybrid_sigma_pressure_coordinate", "type": "standard_name", "name": "atmosphere_hybrid_sigma_pressure_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/atmosphere_kinetic_energy_content.json b/data_descriptors/standard_name/atmosphere_kinetic_energy_content.json index 3c5f1bcfb..6d782bf36 100644 --- a/data_descriptors/standard_name/atmosphere_kinetic_energy_content.json +++ b/data_descriptors/standard_name/atmosphere_kinetic_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_kinetic_energy_content", + "id": "atmosphere_kinetic_energy_content", "type": "standard_name", "name": "atmosphere_kinetic_energy_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_layer_thickness_expressed_as_geopotential_height_difference.json b/data_descriptors/standard_name/atmosphere_layer_thickness_expressed_as_geopotential_height_difference.json index ec991f589..152a978bd 100644 --- a/data_descriptors/standard_name/atmosphere_layer_thickness_expressed_as_geopotential_height_difference.json +++ b/data_descriptors/standard_name/atmosphere_layer_thickness_expressed_as_geopotential_height_difference.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_layer_thickness_expressed_as_geopotential_height_difference", + "id": "atmosphere_layer_thickness_expressed_as_geopotential_height_difference", "type": "standard_name", "name": "atmosphere_layer_thickness_expressed_as_geopotential_height_difference", "description": "The quantity with standard name atmosphere_layer_thickness_expressed_as_geopotential_height_difference is the difference of geopotential height between two atmospheric levels. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. \"Thickness\" means the vertical extent of a layer. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name \"height\", which is relative to the surface.", diff --git a/data_descriptors/standard_name/atmosphere_level_of_free_convection.json b/data_descriptors/standard_name/atmosphere_level_of_free_convection.json index e17381d6c..a76437679 100644 --- a/data_descriptors/standard_name/atmosphere_level_of_free_convection.json +++ b/data_descriptors/standard_name/atmosphere_level_of_free_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_level_of_free_convection", + "id": "atmosphere_level_of_free_convection", "type": "standard_name", "name": "atmosphere_level_of_free_convection", "description": "The level of free convection is the altitude where the temperature of the environment decreases faster than the moist adiabatic lapse rate of a saturated air parcel at the same level. It is calculated by lifting a parcel of air dry adiabatically to the LCL (lifted condensation level), then moist adiabatically until the parcel temperature is equal to the ambient temperature. A coordinate variable of original_air_pressure_of_lifted_parcel should be specified to indicate the starting height of the lifted parcel.", diff --git a/data_descriptors/standard_name/atmosphere_level_of_free_convection_wrt_surface.json b/data_descriptors/standard_name/atmosphere_level_of_free_convection_wrt_surface.json index 698484c3e..b7ea84f48 100644 --- a/data_descriptors/standard_name/atmosphere_level_of_free_convection_wrt_surface.json +++ b/data_descriptors/standard_name/atmosphere_level_of_free_convection_wrt_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_level_of_free_convection_wrt_surface", + "id": "atmosphere_level_of_free_convection_wrt_surface", "type": "standard_name", "name": "atmosphere_level_of_free_convection_wrt_surface", "description": "The level of free convection is the altitude where the temperature of the environment decreases faster than the moist adiabatic lapse rate of a saturated air parcel at the same level. It is calculated by lifting a parcel of air dry adiabatically from the surface to the LCL (lifting condensation level), then moist adiabatically until the parcel temperature is equal to the ambient temperature.", diff --git a/data_descriptors/standard_name/atmosphere_lifting_condensation_level.json b/data_descriptors/standard_name/atmosphere_lifting_condensation_level.json index f23c6f472..64b148e14 100644 --- a/data_descriptors/standard_name/atmosphere_lifting_condensation_level.json +++ b/data_descriptors/standard_name/atmosphere_lifting_condensation_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_lifting_condensation_level", + "id": "atmosphere_lifting_condensation_level", "type": "standard_name", "name": "atmosphere_lifting_condensation_level", "description": "The lifting condensation level is the height at which the relative humidity of an air parcel cooled by dry adiabatic lifting would reach 100%. A coordinate variable of original_air_pressure_of_lifted_parcel should be specified to indicate the starting height of the lifted parcel.", diff --git a/data_descriptors/standard_name/atmosphere_lifting_condensation_level_wrt_surface.json b/data_descriptors/standard_name/atmosphere_lifting_condensation_level_wrt_surface.json index 4757a29e8..29eca2543 100644 --- a/data_descriptors/standard_name/atmosphere_lifting_condensation_level_wrt_surface.json +++ b/data_descriptors/standard_name/atmosphere_lifting_condensation_level_wrt_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_lifting_condensation_level_wrt_surface", + "id": "atmosphere_lifting_condensation_level_wrt_surface", "type": "standard_name", "name": "atmosphere_lifting_condensation_level_wrt_surface", "description": "The lifting condensation level is the height at which the relative humidity of an air parcel cooled by dry adiabatic lifting from the surface would reach 100%.", diff --git a/data_descriptors/standard_name/atmosphere_ln_pressure_coordinate.json b/data_descriptors/standard_name/atmosphere_ln_pressure_coordinate.json index f9d542898..a3b09d51b 100644 --- a/data_descriptors/standard_name/atmosphere_ln_pressure_coordinate.json +++ b/data_descriptors/standard_name/atmosphere_ln_pressure_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_ln_pressure_coordinate", + "id": "atmosphere_ln_pressure_coordinate", "type": "standard_name", "name": "atmosphere_ln_pressure_coordinate", "description": "\"ln_X\" means natural logarithm of X. X must be dimensionless. See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_acetic_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_acetic_acid.json index 1f26993e0..51d2e1900 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_acetic_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_acetic_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_acetic_acid", + "id": "atmosphere_mass_content_of_acetic_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_acetic_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_aceto_nitrile.json b/data_descriptors/standard_name/atmosphere_mass_content_of_aceto_nitrile.json index e78a2afe7..27d2404cc 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_aceto_nitrile.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_aceto_nitrile.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_aceto_nitrile", + "id": "atmosphere_mass_content_of_aceto_nitrile", "type": "standard_name", "name": "atmosphere_mass_content_of_aceto_nitrile", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_alkanes.json b/data_descriptors/standard_name/atmosphere_mass_content_of_alkanes.json index ce768ce86..bbd49da6b 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_alkanes.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_alkanes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_alkanes", + "id": "atmosphere_mass_content_of_alkanes", "type": "standard_name", "name": "atmosphere_mass_content_of_alkanes", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Alkanes are saturated hydrocarbons, i.e. they do not contain any chemical double bonds. Alkanes contain only hydrogen and carbon combined in the general proportions C(n)H(2n+2); \"alkanes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkane species, e.g., methane and ethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_alkenes.json b/data_descriptors/standard_name/atmosphere_mass_content_of_alkenes.json index 17c4a8c36..a4f04a7a1 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_alkenes.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_alkenes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_alkenes", + "id": "atmosphere_mass_content_of_alkenes", "type": "standard_name", "name": "atmosphere_mass_content_of_alkenes", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Alkenes are unsaturated hydrocarbons as they contain chemical double bonds between adjacent carbon atoms. Alkenes contain only hydrogen and carbon combined in the general proportions C(n)H(2n); \"alkenes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkene species, e.g., ethene and propene.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_hexachlorocyclohexane.json b/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_hexachlorocyclohexane.json index 6faae5a57..b8c86539a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_hexachlorocyclohexane.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_hexachlorocyclohexane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_alpha_hexachlorocyclohexane", + "id": "atmosphere_mass_content_of_alpha_hexachlorocyclohexane", "type": "standard_name", "name": "atmosphere_mass_content_of_alpha_hexachlorocyclohexane", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for alpha_hexachlorocyclohexane is C6H6Cl6.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_pinene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_pinene.json index e69b9c670..d1cb2ece9 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_pinene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_alpha_pinene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_alpha_pinene", + "id": "atmosphere_mass_content_of_alpha_pinene", "type": "standard_name", "name": "atmosphere_mass_content_of_alpha_pinene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ammonia.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ammonia.json index 5888b4a69..9e2bc6266 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ammonia.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ammonia.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ammonia", + "id": "atmosphere_mass_content_of_ammonia", "type": "standard_name", "name": "atmosphere_mass_content_of_ammonia", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ammonium_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ammonium_dry_aerosol_particles.json index 6d29b87a3..bd6825579 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ammonium_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ammonium_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ammonium_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_ammonium_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_ammonium_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for ammonium is NH4.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon.json index 432230748..5523d7f61 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon", + "id": "atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "atmosphere_mass_content_of_anthropogenic_nmvoc_expressed_as_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_aromatic_compounds.json b/data_descriptors/standard_name/atmosphere_mass_content_of_aromatic_compounds.json index ab9237ece..8ad1d2e2f 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_aromatic_compounds.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_aromatic_compounds.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_aromatic_compounds", + "id": "atmosphere_mass_content_of_aromatic_compounds", "type": "standard_name", "name": "atmosphere_mass_content_of_aromatic_compounds", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Aromatic compounds in organic chemistry are compounds that contain at least one benzene ring of six carbon atoms joined by alternating single and double covalent bonds. The simplest aromatic compound is benzene itself. In standard names \"aromatic_compounds\" is the term used to describe the group of aromatic chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual aromatic species, e.g. benzene and xylene.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_bromine.json b/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_bromine.json index bc0814225..f20551206 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_bromine.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_atomic_bromine", + "id": "atmosphere_mass_content_of_atomic_bromine", "type": "standard_name", "name": "atmosphere_mass_content_of_atomic_bromine", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical symbol for atomic bromine is Br.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_chlorine.json b/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_chlorine.json index fcd6ebae6..518198862 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_chlorine.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_atomic_chlorine", + "id": "atmosphere_mass_content_of_atomic_chlorine", "type": "standard_name", "name": "atmosphere_mass_content_of_atomic_chlorine", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical symbol for atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_nitrogen.json b/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_nitrogen.json index 3ef51e37d..508badd26 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_nitrogen.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_atomic_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_atomic_nitrogen", + "id": "atmosphere_mass_content_of_atomic_nitrogen", "type": "standard_name", "name": "atmosphere_mass_content_of_atomic_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical symbol for atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_benzene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_benzene.json index 682b181a9..a6e11222b 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_benzene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_benzene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_benzene", + "id": "atmosphere_mass_content_of_benzene", "type": "standard_name", "name": "atmosphere_mass_content_of_benzene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_beta_pinene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_beta_pinene.json index 918d568ae..3f9cca691 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_beta_pinene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_beta_pinene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_beta_pinene", + "id": "atmosphere_mass_content_of_beta_pinene", "type": "standard_name", "name": "atmosphere_mass_content_of_beta_pinene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon.json index 7c4f835ff..76f831a65 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon", + "id": "atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_chloride.json b/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_chloride.json index e45d7775a..6b4742681 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_chloride.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_bromine_chloride", + "id": "atmosphere_mass_content_of_bromine_chloride", "type": "standard_name", "name": "atmosphere_mass_content_of_bromine_chloride", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_monoxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_monoxide.json index c4df3a2d4..b75f96642 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_bromine_monoxide", + "id": "atmosphere_mass_content_of_bromine_monoxide", "type": "standard_name", "name": "atmosphere_mass_content_of_bromine_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_nitrate.json b/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_nitrate.json index 4ab903cde..323cc12fa 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_nitrate.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_bromine_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_bromine_nitrate", + "id": "atmosphere_mass_content_of_bromine_nitrate", "type": "standard_name", "name": "atmosphere_mass_content_of_bromine_nitrate", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for bromine nitrate is BrONO2. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_brox_expressed_as_bromine.json b/data_descriptors/standard_name/atmosphere_mass_content_of_brox_expressed_as_bromine.json index 4034d5c1b..22aabf10c 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_brox_expressed_as_bromine.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_brox_expressed_as_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_brox_expressed_as_bromine", + "id": "atmosphere_mass_content_of_brox_expressed_as_bromine", "type": "standard_name", "name": "atmosphere_mass_content_of_brox_expressed_as_bromine", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer are used\". \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_butane.json b/data_descriptors/standard_name/atmosphere_mass_content_of_butane.json index d54a28423..c4f94f559 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_butane.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_butane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_butane", + "id": "atmosphere_mass_content_of_butane", "type": "standard_name", "name": "atmosphere_mass_content_of_butane", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_dioxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_dioxide.json index 8b5a79aba..6ff5d9128 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_carbon_dioxide", + "id": "atmosphere_mass_content_of_carbon_dioxide", "type": "standard_name", "name": "atmosphere_mass_content_of_carbon_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_monoxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_monoxide.json index da36df4f7..0e306ee76 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_carbon_monoxide", + "id": "atmosphere_mass_content_of_carbon_monoxide", "type": "standard_name", "name": "atmosphere_mass_content_of_carbon_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_tetrachloride.json b/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_tetrachloride.json index 60069b88b..8ddf34b41 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_tetrachloride.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_carbon_tetrachloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_carbon_tetrachloride", + "id": "atmosphere_mass_content_of_carbon_tetrachloride", "type": "standard_name", "name": "atmosphere_mass_content_of_carbon_tetrachloride", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc11.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc11.json index 7bfec1a62..02107bd57 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc11.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc11.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cfc11", + "id": "atmosphere_mass_content_of_cfc11", "type": "standard_name", "name": "atmosphere_mass_content_of_cfc11", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113.json index 125cf3fa5..3acfc80e3 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cfc113", + "id": "atmosphere_mass_content_of_cfc113", "type": "standard_name", "name": "atmosphere_mass_content_of_cfc113", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113a.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113a.json index dfdccfd92..2c02b234c 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113a.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc113a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cfc113a", + "id": "atmosphere_mass_content_of_cfc113a", "type": "standard_name", "name": "atmosphere_mass_content_of_cfc113a", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc114.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc114.json index 676420cbc..a5978c97f 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc114.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc114.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cfc114", + "id": "atmosphere_mass_content_of_cfc114", "type": "standard_name", "name": "atmosphere_mass_content_of_cfc114", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc115.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc115.json index abe620890..af1c6699f 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc115.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc115.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cfc115", + "id": "atmosphere_mass_content_of_cfc115", "type": "standard_name", "name": "atmosphere_mass_content_of_cfc115", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc12.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc12.json index 3f9b499e5..8c75eb77a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cfc12.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cfc12.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cfc12", + "id": "atmosphere_mass_content_of_cfc12", "type": "standard_name", "name": "atmosphere_mass_content_of_cfc12", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_dioxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_dioxide.json index 2052126b0..eff42d3f9 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_chlorine_dioxide", + "id": "atmosphere_mass_content_of_chlorine_dioxide", "type": "standard_name", "name": "atmosphere_mass_content_of_chlorine_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_monoxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_monoxide.json index 92cf036d3..4726df05a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_chlorine_monoxide", + "id": "atmosphere_mass_content_of_chlorine_monoxide", "type": "standard_name", "name": "atmosphere_mass_content_of_chlorine_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_nitrate.json b/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_nitrate.json index 321bd97e0..ab3df6bd6 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_nitrate.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_chlorine_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_chlorine_nitrate", + "id": "atmosphere_mass_content_of_chlorine_nitrate", "type": "standard_name", "name": "atmosphere_mass_content_of_chlorine_nitrate", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_condensed_water.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_condensed_water.json index f0ddeefac..7658534f6 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_condensed_water.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_condensed_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cloud_condensed_water", + "id": "atmosphere_mass_content_of_cloud_condensed_water", "type": "standard_name", "name": "atmosphere_mass_content_of_cloud_condensed_water", "description": "The phrase \"condensed_water\" means liquid and ice. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_ice.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_ice.json index e06125577..813316327 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_ice.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cloud_ice", + "id": "atmosphere_mass_content_of_cloud_ice", "type": "standard_name", "name": "atmosphere_mass_content_of_cloud_ice", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_liquid_water.json b/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_liquid_water.json index adb7d0a32..cdea13b37 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_liquid_water.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_cloud_liquid_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_cloud_liquid_water", + "id": "atmosphere_mass_content_of_cloud_liquid_water", "type": "standard_name", "name": "atmosphere_mass_content_of_cloud_liquid_water", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_clox_expressed_as_chlorine.json b/data_descriptors/standard_name/atmosphere_mass_content_of_clox_expressed_as_chlorine.json index 563630d1d..7b5590f8f 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_clox_expressed_as_chlorine.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_clox_expressed_as_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_clox_expressed_as_chlorine", + "id": "atmosphere_mass_content_of_clox_expressed_as_chlorine", "type": "standard_name", "name": "atmosphere_mass_content_of_clox_expressed_as_chlorine", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_condensed_water.json b/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_condensed_water.json index 5e124a21c..1ade9ab99 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_condensed_water.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_condensed_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_convective_cloud_condensed_water", + "id": "atmosphere_mass_content_of_convective_cloud_condensed_water", "type": "standard_name", "name": "atmosphere_mass_content_of_convective_cloud_condensed_water", "description": "The phrase \"condensed_water\" means liquid and ice. Convective cloud is that produced by the convection schemes in an atmosphere model. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_ice.json b/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_ice.json index 65c981dc3..8412fe994 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_ice.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_convective_cloud_ice", + "id": "atmosphere_mass_content_of_convective_cloud_ice", "type": "standard_name", "name": "atmosphere_mass_content_of_convective_cloud_ice", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_liquid_water.json b/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_liquid_water.json index 693dd3107..429013400 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_liquid_water.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_convective_cloud_liquid_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_convective_cloud_liquid_water", + "id": "atmosphere_mass_content_of_convective_cloud_liquid_water", "type": "standard_name", "name": "atmosphere_mass_content_of_convective_cloud_liquid_water", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Convective cloud is that produced by the convection schemes in an atmosphere model. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_dichlorine_peroxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_dichlorine_peroxide.json index 2fc7b6dc5..76a056c41 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_dichlorine_peroxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_dichlorine_peroxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_dichlorine_peroxide", + "id": "atmosphere_mass_content_of_dichlorine_peroxide", "type": "standard_name", "name": "atmosphere_mass_content_of_dichlorine_peroxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_dimethyl_sulfide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_dimethyl_sulfide.json index a587af38f..e59fb6d27 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_dimethyl_sulfide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_dimethyl_sulfide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_dimethyl_sulfide", + "id": "atmosphere_mass_content_of_dimethyl_sulfide", "type": "standard_name", "name": "atmosphere_mass_content_of_dimethyl_sulfide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_dinitrogen_pentoxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_dinitrogen_pentoxide.json index 774838e57..ff0fdbdaa 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_dinitrogen_pentoxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_dinitrogen_pentoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_dinitrogen_pentoxide", + "id": "atmosphere_mass_content_of_dinitrogen_pentoxide", "type": "standard_name", "name": "atmosphere_mass_content_of_dinitrogen_pentoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_dust_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_dust_dry_aerosol_particles.json index 56b54fa0e..3f5fc3185 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_dust_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_dust_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_dust_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_dust_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_dust_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles.json index 839c803b6..00e639efe 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ethane.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ethane.json index c372943fa..47c00428a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ethane.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ethane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ethane", + "id": "atmosphere_mass_content_of_ethane", "type": "standard_name", "name": "atmosphere_mass_content_of_ethane", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ethanol.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ethanol.json index 9596a23c2..99dcef0b4 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ethanol.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ethanol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ethanol", + "id": "atmosphere_mass_content_of_ethanol", "type": "standard_name", "name": "atmosphere_mass_content_of_ethanol", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ethene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ethene.json index 8b5be5f48..6fa500a69 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ethene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ethene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ethene", + "id": "atmosphere_mass_content_of_ethene", "type": "standard_name", "name": "atmosphere_mass_content_of_ethene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ethyne.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ethyne.json index 17841b2ff..51a71da62 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ethyne.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ethyne.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ethyne", + "id": "atmosphere_mass_content_of_ethyne", "type": "standard_name", "name": "atmosphere_mass_content_of_ethyne", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_formaldehyde.json b/data_descriptors/standard_name/atmosphere_mass_content_of_formaldehyde.json index 240c523e0..ff9fa32f8 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_formaldehyde.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_formaldehyde.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_formaldehyde", + "id": "atmosphere_mass_content_of_formaldehyde", "type": "standard_name", "name": "atmosphere_mass_content_of_formaldehyde", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_formic_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_formic_acid.json index 3597fd89f..286598bb8 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_formic_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_formic_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_formic_acid", + "id": "atmosphere_mass_content_of_formic_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_formic_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_divalent_mercury.json b/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_divalent_mercury.json index 64fd902b1..b7ee67f4d 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_divalent_mercury.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_divalent_mercury.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_gaseous_divalent_mercury", + "id": "atmosphere_mass_content_of_gaseous_divalent_mercury", "type": "standard_name", "name": "atmosphere_mass_content_of_gaseous_divalent_mercury", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_elemental_mercury.json b/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_elemental_mercury.json index 01162ecc2..bbbb8bc4d 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_elemental_mercury.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_gaseous_elemental_mercury.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_gaseous_elemental_mercury", + "id": "atmosphere_mass_content_of_gaseous_elemental_mercury", "type": "standard_name", "name": "atmosphere_mass_content_of_gaseous_elemental_mercury", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical symbol for mercury is Hg.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_graupel.json b/data_descriptors/standard_name/atmosphere_mass_content_of_graupel.json index 37c4bc663..dea80736b 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_graupel.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_graupel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_graupel", + "id": "atmosphere_mass_content_of_graupel", "type": "standard_name", "name": "atmosphere_mass_content_of_graupel", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. There are also separate standard names for hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_graupel_and_hail.json b/data_descriptors/standard_name/atmosphere_mass_content_of_graupel_and_hail.json index dc6f37584..348cb1eeb 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_graupel_and_hail.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_graupel_and_hail.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_graupel_and_hail", + "id": "atmosphere_mass_content_of_graupel_and_hail", "type": "standard_name", "name": "atmosphere_mass_content_of_graupel_and_hail", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel. For models that do distinguish between them, separate standard names for hail and graupel are available.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hail.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hail.json index b49c75e8b..858c74988 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hail.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hail.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hail", + "id": "atmosphere_mass_content_of_hail", "type": "standard_name", "name": "atmosphere_mass_content_of_hail", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. For diameters of less than 5 mm standard names for \"graupel\" should be used. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_halon1202.json b/data_descriptors/standard_name/atmosphere_mass_content_of_halon1202.json index c3add0e64..6d13198f4 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_halon1202.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_halon1202.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_halon1202", + "id": "atmosphere_mass_content_of_halon1202", "type": "standard_name", "name": "atmosphere_mass_content_of_halon1202", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_halon1211.json b/data_descriptors/standard_name/atmosphere_mass_content_of_halon1211.json index a35286e64..3590961eb 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_halon1211.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_halon1211.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_halon1211", + "id": "atmosphere_mass_content_of_halon1211", "type": "standard_name", "name": "atmosphere_mass_content_of_halon1211", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_halon1301.json b/data_descriptors/standard_name/atmosphere_mass_content_of_halon1301.json index 64a274635..856749d58 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_halon1301.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_halon1301.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_halon1301", + "id": "atmosphere_mass_content_of_halon1301", "type": "standard_name", "name": "atmosphere_mass_content_of_halon1301", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer are used\". The mass is the total mass of the molecules. The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_halon2402.json b/data_descriptors/standard_name/atmosphere_mass_content_of_halon2402.json index 3687ad2e5..4225a1ca4 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_halon2402.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_halon2402.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_halon2402", + "id": "atmosphere_mass_content_of_halon2402", "type": "standard_name", "name": "atmosphere_mass_content_of_halon2402", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hcc140a.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hcc140a.json index 369251eb4..08fe06ccd 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hcc140a.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hcc140a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hcc140a", + "id": "atmosphere_mass_content_of_hcc140a", "type": "standard_name", "name": "atmosphere_mass_content_of_hcc140a", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc141b.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc141b.json index 487d28f68..e3fb2468e 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc141b.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc141b.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hcfc141b", + "id": "atmosphere_mass_content_of_hcfc141b", "type": "standard_name", "name": "atmosphere_mass_content_of_hcfc141b", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc142b.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc142b.json index d15d02f2b..90d1c0694 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc142b.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc142b.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hcfc142b", + "id": "atmosphere_mass_content_of_hcfc142b", "type": "standard_name", "name": "atmosphere_mass_content_of_hcfc142b", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc22.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc22.json index 7d1bd9b75..5a7d8575d 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc22.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hcfc22.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hcfc22", + "id": "atmosphere_mass_content_of_hcfc22", "type": "standard_name", "name": "atmosphere_mass_content_of_hcfc22", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer are used\". The mass is the total mass of the molecules. The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hexachlorobiphenyl.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hexachlorobiphenyl.json index d40c42bf4..eb503aad2 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hexachlorobiphenyl.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hexachlorobiphenyl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hexachlorobiphenyl", + "id": "atmosphere_mass_content_of_hexachlorobiphenyl", "type": "standard_name", "name": "atmosphere_mass_content_of_hexachlorobiphenyl", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The chemical formula for hexachlorobiphenyl is C12H4Cl6. The structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hox_expressed_as_hydrogen.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hox_expressed_as_hydrogen.json index 5cd888e22..a9fd5a4f2 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hox_expressed_as_hydrogen.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hox_expressed_as_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hox_expressed_as_hydrogen", + "id": "atmosphere_mass_content_of_hox_expressed_as_hydrogen", "type": "standard_name", "name": "atmosphere_mass_content_of_hox_expressed_as_hydrogen", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"HOx\" means a combination of two radical species containing hydrogen and oxygen: OH and HO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_bromide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_bromide.json index 23321ba03..45f626307 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_bromide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hydrogen_bromide", + "id": "atmosphere_mass_content_of_hydrogen_bromide", "type": "standard_name", "name": "atmosphere_mass_content_of_hydrogen_bromide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The chemical formula for hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_chloride.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_chloride.json index 1b147e0ca..f36307f78 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_chloride.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hydrogen_chloride", + "id": "atmosphere_mass_content_of_hydrogen_chloride", "type": "standard_name", "name": "atmosphere_mass_content_of_hydrogen_chloride", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_cyanide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_cyanide.json index 9800d6a8c..da737d7c6 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_cyanide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_cyanide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hydrogen_cyanide", + "id": "atmosphere_mass_content_of_hydrogen_cyanide", "type": "standard_name", "name": "atmosphere_mass_content_of_hydrogen_cyanide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_peroxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_peroxide.json index 166396a4f..ede3feb35 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_peroxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hydrogen_peroxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hydrogen_peroxide", + "id": "atmosphere_mass_content_of_hydrogen_peroxide", "type": "standard_name", "name": "atmosphere_mass_content_of_hydrogen_peroxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hydroperoxyl_radical.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hydroperoxyl_radical.json index 682cccd4b..de19e9458 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hydroperoxyl_radical.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hydroperoxyl_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hydroperoxyl_radical", + "id": "atmosphere_mass_content_of_hydroperoxyl_radical", "type": "standard_name", "name": "atmosphere_mass_content_of_hydroperoxyl_radical", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for the hydroperoxyl radical is HO2. In chemistry, a 'radical' is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hydroxyl_radical.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hydroxyl_radical.json index ba8640b4e..57509e0bd 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hydroxyl_radical.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hydroxyl_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hydroxyl_radical", + "id": "atmosphere_mass_content_of_hydroxyl_radical", "type": "standard_name", "name": "atmosphere_mass_content_of_hydroxyl_radical", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hypobromous_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hypobromous_acid.json index f97114ea9..a2cd07aeb 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hypobromous_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hypobromous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hypobromous_acid", + "id": "atmosphere_mass_content_of_hypobromous_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_hypobromous_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_hypochlorous_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_hypochlorous_acid.json index 0a1851f91..6fb703b84 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_hypochlorous_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_hypochlorous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_hypochlorous_acid", + "id": "atmosphere_mass_content_of_hypochlorous_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_hypochlorous_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_bromine.json b/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_bromine.json index 1ba7b6da5..edbc89b94 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_bromine.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_inorganic_bromine", + "id": "atmosphere_mass_content_of_inorganic_bromine", "type": "standard_name", "name": "atmosphere_mass_content_of_inorganic_bromine", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_chlorine.json b/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_chlorine.json index c63d28d81..0b2cde223 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_chlorine.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_inorganic_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_inorganic_chlorine", + "id": "atmosphere_mass_content_of_inorganic_chlorine", "type": "standard_name", "name": "atmosphere_mass_content_of_inorganic_chlorine", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. \"Inorganic chlorine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"clox\" are used for quantities that contain all inorganic chlorine species except HCl and ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_isoprene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_isoprene.json index 1f50786aa..9bad3c492 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_isoprene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_isoprene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_isoprene", + "id": "atmosphere_mass_content_of_isoprene", "type": "standard_name", "name": "atmosphere_mass_content_of_isoprene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_limonene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_limonene.json index 887a79bba..ec4dd2e66 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_limonene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_limonene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_limonene", + "id": "atmosphere_mass_content_of_limonene", "type": "standard_name", "name": "atmosphere_mass_content_of_limonene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_liquid_precipitation.json b/data_descriptors/standard_name/atmosphere_mass_content_of_liquid_precipitation.json index c8adfdf42..fed9b18ba 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_liquid_precipitation.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_liquid_precipitation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_liquid_precipitation", + "id": "atmosphere_mass_content_of_liquid_precipitation", "type": "standard_name", "name": "atmosphere_mass_content_of_liquid_precipitation", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Liquid_precipitation\" includes both \"rain\" and \"drizzle\". \"Rain\" means drops of water falling through the atmosphere that have a diameter greater than 0.5 mm. \"Drizzle\" means drops of water falling through the atmosphere that have a diameter typically in the range 0.2-0.5 mm.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_mercury_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_mercury_dry_aerosol_particles.json index 246947063..5b9a403fa 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_mercury_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_mercury_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_mercury_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_mercury_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_mercury_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_methane.json b/data_descriptors/standard_name/atmosphere_mass_content_of_methane.json index cd6301dd2..ef326b8e8 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_methane.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_methane", + "id": "atmosphere_mass_content_of_methane", "type": "standard_name", "name": "atmosphere_mass_content_of_methane", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_methanol.json b/data_descriptors/standard_name/atmosphere_mass_content_of_methanol.json index 8a01c9755..050d41694 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_methanol.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_methanol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_methanol", + "id": "atmosphere_mass_content_of_methanol", "type": "standard_name", "name": "atmosphere_mass_content_of_methanol", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_bromide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_bromide.json index 6d5051f1e..f7187b374 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_bromide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_methyl_bromide", + "id": "atmosphere_mass_content_of_methyl_bromide", "type": "standard_name", "name": "atmosphere_mass_content_of_methyl_bromide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_chloride.json b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_chloride.json index ea1d213b2..7483c431e 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_chloride.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_methyl_chloride", + "id": "atmosphere_mass_content_of_methyl_chloride", "type": "standard_name", "name": "atmosphere_mass_content_of_methyl_chloride", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_hydroperoxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_hydroperoxide.json index a9d1a8cbb..c3ae75183 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_hydroperoxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_hydroperoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_methyl_hydroperoxide", + "id": "atmosphere_mass_content_of_methyl_hydroperoxide", "type": "standard_name", "name": "atmosphere_mass_content_of_methyl_hydroperoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_peroxy_radical.json b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_peroxy_radical.json index 51ba545b9..87f683aed 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_peroxy_radical.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_methyl_peroxy_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_methyl_peroxy_radical", + "id": "atmosphere_mass_content_of_methyl_peroxy_radical", "type": "standard_name", "name": "atmosphere_mass_content_of_methyl_peroxy_radical", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for methyl_peroxy_radical is CH3O2. In chemistry, a \"radical\"is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_molecular_hydrogen.json b/data_descriptors/standard_name/atmosphere_mass_content_of_molecular_hydrogen.json index 95f6cafc0..3679b9ff3 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_molecular_hydrogen.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_molecular_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_molecular_hydrogen", + "id": "atmosphere_mass_content_of_molecular_hydrogen", "type": "standard_name", "name": "atmosphere_mass_content_of_molecular_hydrogen", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_dry_aerosol_particles.json index 163ea6d1a..c81ed3a8a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitrate_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_nitrate_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_nitrate_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_radical.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_radical.json index 2cb6225ff..4bf924d8a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_radical.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrate_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitrate_radical", + "id": "atmosphere_mass_content_of_nitrate_radical", "type": "standard_name", "name": "atmosphere_mass_content_of_nitrate_radical", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for nitrate is NO3. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid.json index e70492242..fa818d1c7 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitric_acid", + "id": "atmosphere_mass_content_of_nitric_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_nitric_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles.json index 0c282dd19..3ae6fed57 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles", + "id": "atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_nitric_acid_trihydrate_ambient_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid. The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrogen_monoxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrogen_monoxide.json index 4313c256e..45ffa1bd7 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrogen_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrogen_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitrogen_monoxide", + "id": "atmosphere_mass_content_of_nitrogen_monoxide", "type": "standard_name", "name": "atmosphere_mass_content_of_nitrogen_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_acid.json index 789fede53..358124f7c 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitrous_acid", + "id": "atmosphere_mass_content_of_nitrous_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_nitrous_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_oxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_oxide.json index 6d4d0082f..a1cdaa50e 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_oxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nitrous_oxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nitrous_oxide", + "id": "atmosphere_mass_content_of_nitrous_oxide", "type": "standard_name", "name": "atmosphere_mass_content_of_nitrous_oxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nmvoc_expressed_as_carbon.json index 54f65eeaf..c1448706e 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nmvoc_expressed_as_carbon", + "id": "atmosphere_mass_content_of_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "atmosphere_mass_content_of_nmvoc_expressed_as_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_nox_expressed_as_nitrogen.json b/data_descriptors/standard_name/atmosphere_mass_content_of_nox_expressed_as_nitrogen.json index 35e67f37a..851f8c607 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_nox_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_nox_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_nox_expressed_as_nitrogen", + "id": "atmosphere_mass_content_of_nox_expressed_as_nitrogen", "type": "standard_name", "name": "atmosphere_mass_content_of_nox_expressed_as_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_noy_expressed_as_nitrogen.json b/data_descriptors/standard_name/atmosphere_mass_content_of_noy_expressed_as_nitrogen.json index 2c2b436df..92bf7eb26 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_noy_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_noy_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_noy_expressed_as_nitrogen", + "id": "atmosphere_mass_content_of_noy_expressed_as_nitrogen", "type": "standard_name", "name": "atmosphere_mass_content_of_noy_expressed_as_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_oxygenated_hydrocarbons.json b/data_descriptors/standard_name/atmosphere_mass_content_of_oxygenated_hydrocarbons.json index 13d16f9aa..0c68cf946 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_oxygenated_hydrocarbons.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_oxygenated_hydrocarbons.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_oxygenated_hydrocarbons", + "id": "atmosphere_mass_content_of_oxygenated_hydrocarbons", "type": "standard_name", "name": "atmosphere_mass_content_of_oxygenated_hydrocarbons", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Oxygenated\" means containing oxygen. \"Hydrocarbon\" means a compound containing hydrogen and carbon.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_ozone.json b/data_descriptors/standard_name/atmosphere_mass_content_of_ozone.json index 117dcde09..f1c2e52d7 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_ozone.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_ozone", + "id": "atmosphere_mass_content_of_ozone", "type": "standard_name", "name": "atmosphere_mass_content_of_ozone", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ozone is O3.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles.json index 62663c580..71cc2d23a 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_peroxy_radicals.json b/data_descriptors/standard_name/atmosphere_mass_content_of_peroxy_radicals.json index 04ac36ec1..64c5feb52 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_peroxy_radicals.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_peroxy_radicals.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_peroxy_radicals", + "id": "atmosphere_mass_content_of_peroxy_radicals", "type": "standard_name", "name": "atmosphere_mass_content_of_peroxy_radicals", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The term \"peroxy_radicals\" means all organic and inorganic peroxy radicals. This includes HO2 and all organic peroxy radicals, sometimes referred to as RO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_peroxyacetyl_nitrate.json b/data_descriptors/standard_name/atmosphere_mass_content_of_peroxyacetyl_nitrate.json index c7393cb1c..01f7cb47f 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_peroxyacetyl_nitrate.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_peroxyacetyl_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_peroxyacetyl_nitrate", + "id": "atmosphere_mass_content_of_peroxyacetyl_nitrate", "type": "standard_name", "name": "atmosphere_mass_content_of_peroxyacetyl_nitrate", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl_nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_peroxynitric_acid.json b/data_descriptors/standard_name/atmosphere_mass_content_of_peroxynitric_acid.json index 3f3fd444a..9af3083c0 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_peroxynitric_acid.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_peroxynitric_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_peroxynitric_acid", + "id": "atmosphere_mass_content_of_peroxynitric_acid", "type": "standard_name", "name": "atmosphere_mass_content_of_peroxynitric_acid", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles.json index 742a15c32..97d10382b 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Primary particulate organic matter \" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_propane.json b/data_descriptors/standard_name/atmosphere_mass_content_of_propane.json index b30ee6d34..f0712a246 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_propane.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_propane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_propane", + "id": "atmosphere_mass_content_of_propane", "type": "standard_name", "name": "atmosphere_mass_content_of_propane", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_propene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_propene.json index 8b218c82b..dc2152446 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_propene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_propene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_propene", + "id": "atmosphere_mass_content_of_propene", "type": "standard_name", "name": "atmosphere_mass_content_of_propene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_radon.json b/data_descriptors/standard_name/atmosphere_mass_content_of_radon.json index 10eab46b3..b10740a3d 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_radon.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_radon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_radon", + "id": "atmosphere_mass_content_of_radon", "type": "standard_name", "name": "atmosphere_mass_content_of_radon", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles.json index 69ce29656..43148f41d 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_sea_salt_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_sea_salt_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations.json index 9d186a6c4..14d0446a8 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations", + "id": "atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations", "type": "standard_name", "name": "atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_expressed_as_cations", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles.json index d081a97ab..eeb9fa2ce 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Secondary particulate organic matter \" means particulate organic matter formed within the atmosphere from gaseous precursors. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_snow.json b/data_descriptors/standard_name/atmosphere_mass_content_of_snow.json index 9cede294c..4dbb53abf 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_snow.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_snow", + "id": "atmosphere_mass_content_of_snow", "type": "standard_name", "name": "atmosphere_mass_content_of_snow", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Snow\" refers to the precipitating part of snow in the atmosphere \u2013 the cloud snow content is excluded.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate.json index 80fe85aa1..e9037d427 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sulfate", + "id": "atmosphere_mass_content_of_sulfate", "type": "standard_name", "name": "atmosphere_mass_content_of_sulfate", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_ambient_aerosol_particles.json index cf24d264e..4a626f465 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sulfate_ambient_aerosol_particles", + "id": "atmosphere_mass_content_of_sulfate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_sulfate_ambient_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles.json index ff2edac00..685435f2e 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles", + "id": "atmosphere_mass_content_of_sulfate_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_sulfate_dry_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur.json index 8470c303b..e78e7f002 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur", + "id": "atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur", "type": "standard_name", "name": "atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfur_dioxide.json b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfur_dioxide.json index c39258615..88ed6a722 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_sulfur_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_sulfur_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_sulfur_dioxide", + "id": "atmosphere_mass_content_of_sulfur_dioxide", "type": "standard_name", "name": "atmosphere_mass_content_of_sulfur_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_terpenes.json b/data_descriptors/standard_name/atmosphere_mass_content_of_terpenes.json index 484be6f13..8d139f3ac 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_terpenes.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_terpenes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_terpenes", + "id": "atmosphere_mass_content_of_terpenes", "type": "standard_name", "name": "atmosphere_mass_content_of_terpenes", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Terpenes are hydrocarbons, that is, they contain only hydrogen and carbon combined in the general proportions (C5H8)n where n is an integer greater than on equal to one. The term \"terpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual terpene species, e.g., isoprene and limonene.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_toluene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_toluene.json index abe968354..98025328b 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_toluene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_toluene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_toluene", + "id": "atmosphere_mass_content_of_toluene", "type": "standard_name", "name": "atmosphere_mass_content_of_toluene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_volcanic_ash.json b/data_descriptors/standard_name/atmosphere_mass_content_of_volcanic_ash.json index 656705b89..d5aabd9c2 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_volcanic_ash.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_volcanic_ash.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_volcanic_ash", + "id": "atmosphere_mass_content_of_volcanic_ash", "type": "standard_name", "name": "atmosphere_mass_content_of_volcanic_ash", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Volcanic_ash\" means the fine-grained products of explosive volcanic eruptions, such as minerals or crystals, older fragmented rock (e.g. andesite), and glass. Particles within a volcanic ash cloud have diameters less than 2 mm. \"Volcanic_ash\" does not include non-volcanic dust.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_water.json b/data_descriptors/standard_name/atmosphere_mass_content_of_water.json index 50d11b55c..e63433cb2 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_water.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_water", + "id": "atmosphere_mass_content_of_water", "type": "standard_name", "name": "atmosphere_mass_content_of_water", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_water_in_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_mass_content_of_water_in_ambient_aerosol_particles.json index 6ef62c005..6775a200d 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_water_in_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_water_in_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_water_in_ambient_aerosol_particles", + "id": "atmosphere_mass_content_of_water_in_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_mass_content_of_water_in_ambient_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Water\" means water in all phases. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_water_vapor.json b/data_descriptors/standard_name/atmosphere_mass_content_of_water_vapor.json index 82298419a..db4f7d5e9 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_water_vapor.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_water_vapor", + "id": "atmosphere_mass_content_of_water_vapor", "type": "standard_name", "name": "atmosphere_mass_content_of_water_vapor", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/atmosphere_mass_content_of_xylene.json b/data_descriptors/standard_name/atmosphere_mass_content_of_xylene.json index 41206f3ab..3af1acde5 100644 --- a/data_descriptors/standard_name/atmosphere_mass_content_of_xylene.json +++ b/data_descriptors/standard_name/atmosphere_mass_content_of_xylene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_content_of_xylene", + "id": "atmosphere_mass_content_of_xylene", "type": "standard_name", "name": "atmosphere_mass_content_of_xylene", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mass_of_air_per_unit_area.json b/data_descriptors/standard_name/atmosphere_mass_of_air_per_unit_area.json index 6257f17ab..2005318ba 100644 --- a/data_descriptors/standard_name/atmosphere_mass_of_air_per_unit_area.json +++ b/data_descriptors/standard_name/atmosphere_mass_of_air_per_unit_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_of_air_per_unit_area", + "id": "atmosphere_mass_of_air_per_unit_area", "type": "standard_name", "name": "atmosphere_mass_of_air_per_unit_area", "description": "\"Mass_of_air\" means the mass due solely to the gaseous constituents of the atmosphere. The standard name for the mass including precipitation and aerosol particles is atmosphere_mass_per_unit_area.", diff --git a/data_descriptors/standard_name/atmosphere_mass_of_carbon_dioxide.json b/data_descriptors/standard_name/atmosphere_mass_of_carbon_dioxide.json index ef87a06a0..9bef33bea 100644 --- a/data_descriptors/standard_name/atmosphere_mass_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_mass_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_of_carbon_dioxide", + "id": "atmosphere_mass_of_carbon_dioxide", "type": "standard_name", "name": "atmosphere_mass_of_carbon_dioxide", "description": "The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/atmosphere_mass_per_unit_area.json b/data_descriptors/standard_name/atmosphere_mass_per_unit_area.json index 9940fac0e..66de540c0 100644 --- a/data_descriptors/standard_name/atmosphere_mass_per_unit_area.json +++ b/data_descriptors/standard_name/atmosphere_mass_per_unit_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mass_per_unit_area", + "id": "atmosphere_mass_per_unit_area", "type": "standard_name", "name": "atmosphere_mass_per_unit_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell.", diff --git a/data_descriptors/standard_name/atmosphere_mole_content_of_carbon_monoxide.json b/data_descriptors/standard_name/atmosphere_mole_content_of_carbon_monoxide.json index 85014ea17..04eca04bc 100644 --- a/data_descriptors/standard_name/atmosphere_mole_content_of_carbon_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_mole_content_of_carbon_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mole_content_of_carbon_monoxide", + "id": "atmosphere_mole_content_of_carbon_monoxide", "type": "standard_name", "name": "atmosphere_mole_content_of_carbon_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The construction \"atmosphere_mole_content_of_X\" means the vertically integrated number of moles of X above a unit area. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/atmosphere_mole_content_of_methane.json b/data_descriptors/standard_name/atmosphere_mole_content_of_methane.json index 06ec4d51d..ff5ccb573 100644 --- a/data_descriptors/standard_name/atmosphere_mole_content_of_methane.json +++ b/data_descriptors/standard_name/atmosphere_mole_content_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mole_content_of_methane", + "id": "atmosphere_mole_content_of_methane", "type": "standard_name", "name": "atmosphere_mole_content_of_methane", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The construction \"atmosphere_mole_content_of_X\" means the vertically integrated number of moles of X above a unit area. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_mole_content_of_nitrogen_dioxide.json b/data_descriptors/standard_name/atmosphere_mole_content_of_nitrogen_dioxide.json index a78c0c05c..de9ee4565 100644 --- a/data_descriptors/standard_name/atmosphere_mole_content_of_nitrogen_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_mole_content_of_nitrogen_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mole_content_of_nitrogen_dioxide", + "id": "atmosphere_mole_content_of_nitrogen_dioxide", "type": "standard_name", "name": "atmosphere_mole_content_of_nitrogen_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The construction \"atmosphere_mole_content_of_X\" means the vertically integrated number of moles of X above a unit area. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/atmosphere_mole_content_of_ozone.json b/data_descriptors/standard_name/atmosphere_mole_content_of_ozone.json index 635a24e19..546771c83 100644 --- a/data_descriptors/standard_name/atmosphere_mole_content_of_ozone.json +++ b/data_descriptors/standard_name/atmosphere_mole_content_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mole_content_of_ozone", + "id": "atmosphere_mole_content_of_ozone", "type": "standard_name", "name": "atmosphere_mole_content_of_ozone", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The construction \"atmosphere_mole_content_of_X\" means the vertically integrated number of moles of X above a unit area. The chemical formula for ozone is O3. atmosphere_mole_content_of_ozone is usually measured in Dobson Units which are equivalent to 446.2 micromoles m-2. N.B. Data variables containing column content of ozone can be given the standard name of either equivalent_thickness_at_stp_of_atmosphere_ozone_content or atmosphere_mole_content_of_ozone.The latter name is recommended for consistency with mole content names for chemical species other than ozone.", diff --git a/data_descriptors/standard_name/atmosphere_mole_content_of_water_vapor.json b/data_descriptors/standard_name/atmosphere_mole_content_of_water_vapor.json index e18f2d808..076ab1c01 100644 --- a/data_descriptors/standard_name/atmosphere_mole_content_of_water_vapor.json +++ b/data_descriptors/standard_name/atmosphere_mole_content_of_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_mole_content_of_water_vapor", + "id": "atmosphere_mole_content_of_water_vapor", "type": "standard_name", "name": "atmosphere_mole_content_of_water_vapor", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The construction \"atmosphere_mole_content_of_X\" means the vertically integrated number of moles of X above a unit area. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated. The chemical formula for water is H2O.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_acetic_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_acetic_acid.json index 44bc9b819..2b5368ad4 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_acetic_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_acetic_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_acetic_acid", + "id": "atmosphere_moles_of_acetic_acid", "type": "standard_name", "name": "atmosphere_moles_of_acetic_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_aceto_nitrile.json b/data_descriptors/standard_name/atmosphere_moles_of_aceto_nitrile.json index 7c026702a..71d17a9d6 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_aceto_nitrile.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_aceto_nitrile.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_aceto_nitrile", + "id": "atmosphere_moles_of_aceto_nitrile", "type": "standard_name", "name": "atmosphere_moles_of_aceto_nitrile", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_alpha_hexachlorocyclohexane.json b/data_descriptors/standard_name/atmosphere_moles_of_alpha_hexachlorocyclohexane.json index a8b2c0cdc..effd786bc 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_alpha_hexachlorocyclohexane.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_alpha_hexachlorocyclohexane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_alpha_hexachlorocyclohexane", + "id": "atmosphere_moles_of_alpha_hexachlorocyclohexane", "type": "standard_name", "name": "atmosphere_moles_of_alpha_hexachlorocyclohexane", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for alpha_hexachlorocyclohexane is C6H6Cl6.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_alpha_pinene.json b/data_descriptors/standard_name/atmosphere_moles_of_alpha_pinene.json index 37ca23e7a..159cd14cf 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_alpha_pinene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_alpha_pinene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_alpha_pinene", + "id": "atmosphere_moles_of_alpha_pinene", "type": "standard_name", "name": "atmosphere_moles_of_alpha_pinene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_ammonia.json b/data_descriptors/standard_name/atmosphere_moles_of_ammonia.json index 84b4ba9ab..b94c48ed9 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_ammonia.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_ammonia.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_ammonia", + "id": "atmosphere_moles_of_ammonia", "type": "standard_name", "name": "atmosphere_moles_of_ammonia", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json index b605fbd78..dc66dbbf4 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon", + "id": "atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_atomic_bromine.json b/data_descriptors/standard_name/atmosphere_moles_of_atomic_bromine.json index 24ad91a5d..a06231457 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_atomic_bromine.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_atomic_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_atomic_bromine", + "id": "atmosphere_moles_of_atomic_bromine", "type": "standard_name", "name": "atmosphere_moles_of_atomic_bromine", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for atomic bromine is Br.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_atomic_chlorine.json b/data_descriptors/standard_name/atmosphere_moles_of_atomic_chlorine.json index dd8b59452..4a712c136 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_atomic_chlorine.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_atomic_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_atomic_chlorine", + "id": "atmosphere_moles_of_atomic_chlorine", "type": "standard_name", "name": "atmosphere_moles_of_atomic_chlorine", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_atomic_nitrogen.json b/data_descriptors/standard_name/atmosphere_moles_of_atomic_nitrogen.json index 17487d5bd..8fc5f5513 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_atomic_nitrogen.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_atomic_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_atomic_nitrogen", + "id": "atmosphere_moles_of_atomic_nitrogen", "type": "standard_name", "name": "atmosphere_moles_of_atomic_nitrogen", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_benzene.json b/data_descriptors/standard_name/atmosphere_moles_of_benzene.json index 240871d21..ec09ff9c8 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_benzene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_benzene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_benzene", + "id": "atmosphere_moles_of_benzene", "type": "standard_name", "name": "atmosphere_moles_of_benzene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_beta_pinene.json b/data_descriptors/standard_name/atmosphere_moles_of_beta_pinene.json index 3c3ac5f1c..e09da2356 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_beta_pinene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_beta_pinene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_beta_pinene", + "id": "atmosphere_moles_of_beta_pinene", "type": "standard_name", "name": "atmosphere_moles_of_beta_pinene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json index c21aa9377..62a1e3fb2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon", + "id": "atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_bromine_chloride.json b/data_descriptors/standard_name/atmosphere_moles_of_bromine_chloride.json index 0fcc15adc..918cf85bb 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_bromine_chloride.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_bromine_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_bromine_chloride", + "id": "atmosphere_moles_of_bromine_chloride", "type": "standard_name", "name": "atmosphere_moles_of_bromine_chloride", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_bromine_monoxide.json b/data_descriptors/standard_name/atmosphere_moles_of_bromine_monoxide.json index 388f3d5ad..3aa1e361e 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_bromine_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_bromine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_bromine_monoxide", + "id": "atmosphere_moles_of_bromine_monoxide", "type": "standard_name", "name": "atmosphere_moles_of_bromine_monoxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_bromine_nitrate.json b/data_descriptors/standard_name/atmosphere_moles_of_bromine_nitrate.json index a7b4b422e..65a0ee969 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_bromine_nitrate.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_bromine_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_bromine_nitrate", + "id": "atmosphere_moles_of_bromine_nitrate", "type": "standard_name", "name": "atmosphere_moles_of_bromine_nitrate", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for bromine nitrate is BrONO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_brox_expressed_as_bromine.json b/data_descriptors/standard_name/atmosphere_moles_of_brox_expressed_as_bromine.json index f04986b6b..21d690f59 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_brox_expressed_as_bromine.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_brox_expressed_as_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_brox_expressed_as_bromine", + "id": "atmosphere_moles_of_brox_expressed_as_bromine", "type": "standard_name", "name": "atmosphere_moles_of_brox_expressed_as_bromine", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_butane.json b/data_descriptors/standard_name/atmosphere_moles_of_butane.json index 372a71061..90dbfcae2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_butane.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_butane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_butane", + "id": "atmosphere_moles_of_butane", "type": "standard_name", "name": "atmosphere_moles_of_butane", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_carbon_dioxide.json b/data_descriptors/standard_name/atmosphere_moles_of_carbon_dioxide.json index a7c758f74..bc0033010 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_carbon_dioxide", + "id": "atmosphere_moles_of_carbon_dioxide", "type": "standard_name", "name": "atmosphere_moles_of_carbon_dioxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_carbon_monoxide.json b/data_descriptors/standard_name/atmosphere_moles_of_carbon_monoxide.json index 39eeb3e73..7a25e73c0 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_carbon_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_carbon_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_carbon_monoxide", + "id": "atmosphere_moles_of_carbon_monoxide", "type": "standard_name", "name": "atmosphere_moles_of_carbon_monoxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_carbon_tetrachloride.json b/data_descriptors/standard_name/atmosphere_moles_of_carbon_tetrachloride.json index 092b9a8aa..71d1b8e65 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_carbon_tetrachloride.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_carbon_tetrachloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_carbon_tetrachloride", + "id": "atmosphere_moles_of_carbon_tetrachloride", "type": "standard_name", "name": "atmosphere_moles_of_carbon_tetrachloride", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_cfc11.json b/data_descriptors/standard_name/atmosphere_moles_of_cfc11.json index ff44ca36e..2dbeff057 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_cfc11.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_cfc11.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_cfc11", + "id": "atmosphere_moles_of_cfc11", "type": "standard_name", "name": "atmosphere_moles_of_cfc11", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_cfc113.json b/data_descriptors/standard_name/atmosphere_moles_of_cfc113.json index fd0386c1a..c26d3040f 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_cfc113.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_cfc113.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_cfc113", + "id": "atmosphere_moles_of_cfc113", "type": "standard_name", "name": "atmosphere_moles_of_cfc113", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_cfc113a.json b/data_descriptors/standard_name/atmosphere_moles_of_cfc113a.json index e06c406d3..2bd264daf 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_cfc113a.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_cfc113a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_cfc113a", + "id": "atmosphere_moles_of_cfc113a", "type": "standard_name", "name": "atmosphere_moles_of_cfc113a", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_cfc114.json b/data_descriptors/standard_name/atmosphere_moles_of_cfc114.json index 980b6f7e8..0192ee3c9 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_cfc114.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_cfc114.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_cfc114", + "id": "atmosphere_moles_of_cfc114", "type": "standard_name", "name": "atmosphere_moles_of_cfc114", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_cfc115.json b/data_descriptors/standard_name/atmosphere_moles_of_cfc115.json index dc91b061e..8e97d2262 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_cfc115.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_cfc115.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_cfc115", + "id": "atmosphere_moles_of_cfc115", "type": "standard_name", "name": "atmosphere_moles_of_cfc115", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_cfc12.json b/data_descriptors/standard_name/atmosphere_moles_of_cfc12.json index af00cf01e..292a3dd4e 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_cfc12.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_cfc12.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_cfc12", + "id": "atmosphere_moles_of_cfc12", "type": "standard_name", "name": "atmosphere_moles_of_cfc12", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_chlorine_dioxide.json b/data_descriptors/standard_name/atmosphere_moles_of_chlorine_dioxide.json index 8d4fb303f..5b34101f2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_chlorine_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_chlorine_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_chlorine_dioxide", + "id": "atmosphere_moles_of_chlorine_dioxide", "type": "standard_name", "name": "atmosphere_moles_of_chlorine_dioxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_chlorine_monoxide.json b/data_descriptors/standard_name/atmosphere_moles_of_chlorine_monoxide.json index 4ae4c1b26..e5f06e179 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_chlorine_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_chlorine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_chlorine_monoxide", + "id": "atmosphere_moles_of_chlorine_monoxide", "type": "standard_name", "name": "atmosphere_moles_of_chlorine_monoxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_chlorine_nitrate.json b/data_descriptors/standard_name/atmosphere_moles_of_chlorine_nitrate.json index 0aca90074..1c6651fcd 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_chlorine_nitrate.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_chlorine_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_chlorine_nitrate", + "id": "atmosphere_moles_of_chlorine_nitrate", "type": "standard_name", "name": "atmosphere_moles_of_chlorine_nitrate", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_clox_expressed_as_chlorine.json b/data_descriptors/standard_name/atmosphere_moles_of_clox_expressed_as_chlorine.json index 11fe83a6a..a7bcd38e9 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_clox_expressed_as_chlorine.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_clox_expressed_as_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_clox_expressed_as_chlorine", + "id": "atmosphere_moles_of_clox_expressed_as_chlorine", "type": "standard_name", "name": "atmosphere_moles_of_clox_expressed_as_chlorine", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_dichlorine_peroxide.json b/data_descriptors/standard_name/atmosphere_moles_of_dichlorine_peroxide.json index 429c4d6df..1a1e7faba 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_dichlorine_peroxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_dichlorine_peroxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_dichlorine_peroxide", + "id": "atmosphere_moles_of_dichlorine_peroxide", "type": "standard_name", "name": "atmosphere_moles_of_dichlorine_peroxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_dimethyl_sulfide.json b/data_descriptors/standard_name/atmosphere_moles_of_dimethyl_sulfide.json index 1a2c0a812..a21f7a0de 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_dimethyl_sulfide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_dimethyl_sulfide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_dimethyl_sulfide", + "id": "atmosphere_moles_of_dimethyl_sulfide", "type": "standard_name", "name": "atmosphere_moles_of_dimethyl_sulfide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_dinitrogen_pentoxide.json b/data_descriptors/standard_name/atmosphere_moles_of_dinitrogen_pentoxide.json index cb1ca9320..cbae8d57a 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_dinitrogen_pentoxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_dinitrogen_pentoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_dinitrogen_pentoxide", + "id": "atmosphere_moles_of_dinitrogen_pentoxide", "type": "standard_name", "name": "atmosphere_moles_of_dinitrogen_pentoxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_ethane.json b/data_descriptors/standard_name/atmosphere_moles_of_ethane.json index 95607e123..19907cdce 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_ethane.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_ethane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_ethane", + "id": "atmosphere_moles_of_ethane", "type": "standard_name", "name": "atmosphere_moles_of_ethane", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_ethanol.json b/data_descriptors/standard_name/atmosphere_moles_of_ethanol.json index abd5cd4b8..6db751e7b 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_ethanol.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_ethanol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_ethanol", + "id": "atmosphere_moles_of_ethanol", "type": "standard_name", "name": "atmosphere_moles_of_ethanol", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_ethene.json b/data_descriptors/standard_name/atmosphere_moles_of_ethene.json index b364ef993..222001a26 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_ethene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_ethene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_ethene", + "id": "atmosphere_moles_of_ethene", "type": "standard_name", "name": "atmosphere_moles_of_ethene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_ethyne.json b/data_descriptors/standard_name/atmosphere_moles_of_ethyne.json index bf4211ed0..ee3542ef2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_ethyne.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_ethyne.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_ethyne", + "id": "atmosphere_moles_of_ethyne", "type": "standard_name", "name": "atmosphere_moles_of_ethyne", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_formaldehyde.json b/data_descriptors/standard_name/atmosphere_moles_of_formaldehyde.json index 58846ee45..3ab54b12f 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_formaldehyde.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_formaldehyde.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_formaldehyde", + "id": "atmosphere_moles_of_formaldehyde", "type": "standard_name", "name": "atmosphere_moles_of_formaldehyde", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_formic_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_formic_acid.json index 09ebe5e98..2dc04f9ce 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_formic_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_formic_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_formic_acid", + "id": "atmosphere_moles_of_formic_acid", "type": "standard_name", "name": "atmosphere_moles_of_formic_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_gaseous_divalent_mercury.json b/data_descriptors/standard_name/atmosphere_moles_of_gaseous_divalent_mercury.json index 44028b916..4dd1b5d74 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_gaseous_divalent_mercury.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_gaseous_divalent_mercury.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_gaseous_divalent_mercury", + "id": "atmosphere_moles_of_gaseous_divalent_mercury", "type": "standard_name", "name": "atmosphere_moles_of_gaseous_divalent_mercury", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_gaseous_elemental_mercury.json b/data_descriptors/standard_name/atmosphere_moles_of_gaseous_elemental_mercury.json index 99d3a9f5f..a0124c69b 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_gaseous_elemental_mercury.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_gaseous_elemental_mercury.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_gaseous_elemental_mercury", + "id": "atmosphere_moles_of_gaseous_elemental_mercury", "type": "standard_name", "name": "atmosphere_moles_of_gaseous_elemental_mercury", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for mercury is Hg.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_halon1202.json b/data_descriptors/standard_name/atmosphere_moles_of_halon1202.json index d2effeb6a..2d3ee29d6 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_halon1202.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_halon1202.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_halon1202", + "id": "atmosphere_moles_of_halon1202", "type": "standard_name", "name": "atmosphere_moles_of_halon1202", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_halon1211.json b/data_descriptors/standard_name/atmosphere_moles_of_halon1211.json index 6e0d690dd..f320f1cc1 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_halon1211.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_halon1211.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_halon1211", + "id": "atmosphere_moles_of_halon1211", "type": "standard_name", "name": "atmosphere_moles_of_halon1211", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_halon1301.json b/data_descriptors/standard_name/atmosphere_moles_of_halon1301.json index 1ccefd709..fb997416b 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_halon1301.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_halon1301.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_halon1301", + "id": "atmosphere_moles_of_halon1301", "type": "standard_name", "name": "atmosphere_moles_of_halon1301", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_halon2402.json b/data_descriptors/standard_name/atmosphere_moles_of_halon2402.json index 1b0e40f31..f2b9035ed 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_halon2402.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_halon2402.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_halon2402", + "id": "atmosphere_moles_of_halon2402", "type": "standard_name", "name": "atmosphere_moles_of_halon2402", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hcc140a.json b/data_descriptors/standard_name/atmosphere_moles_of_hcc140a.json index 2b420a52e..0d4f27af7 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hcc140a.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hcc140a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hcc140a", + "id": "atmosphere_moles_of_hcc140a", "type": "standard_name", "name": "atmosphere_moles_of_hcc140a", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hcfc141b.json b/data_descriptors/standard_name/atmosphere_moles_of_hcfc141b.json index eef8a8230..35a2c7974 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hcfc141b.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hcfc141b.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hcfc141b", + "id": "atmosphere_moles_of_hcfc141b", "type": "standard_name", "name": "atmosphere_moles_of_hcfc141b", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hcfc142b.json b/data_descriptors/standard_name/atmosphere_moles_of_hcfc142b.json index ba1f76b08..84a56aeab 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hcfc142b.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hcfc142b.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hcfc142b", + "id": "atmosphere_moles_of_hcfc142b", "type": "standard_name", "name": "atmosphere_moles_of_hcfc142b", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hcfc22.json b/data_descriptors/standard_name/atmosphere_moles_of_hcfc22.json index b3d9e1dbb..5acef5920 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hcfc22.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hcfc22.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hcfc22", + "id": "atmosphere_moles_of_hcfc22", "type": "standard_name", "name": "atmosphere_moles_of_hcfc22", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hexachlorobiphenyl.json b/data_descriptors/standard_name/atmosphere_moles_of_hexachlorobiphenyl.json index f9fb15501..72d7cfbd9 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hexachlorobiphenyl.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hexachlorobiphenyl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hexachlorobiphenyl", + "id": "atmosphere_moles_of_hexachlorobiphenyl", "type": "standard_name", "name": "atmosphere_moles_of_hexachlorobiphenyl", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hexachlorobiphenyl is C12H4Cl6. This structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hox_expressed_as_hydrogen.json b/data_descriptors/standard_name/atmosphere_moles_of_hox_expressed_as_hydrogen.json index 978aea298..f5d0dada6 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hox_expressed_as_hydrogen.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hox_expressed_as_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hox_expressed_as_hydrogen", + "id": "atmosphere_moles_of_hox_expressed_as_hydrogen", "type": "standard_name", "name": "atmosphere_moles_of_hox_expressed_as_hydrogen", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"HOx\" means a combination of two radical species containing hydrogen and oxygen: OH and HO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_bromide.json b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_bromide.json index 8f8c4165a..7b6a418a2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_bromide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hydrogen_bromide", + "id": "atmosphere_moles_of_hydrogen_bromide", "type": "standard_name", "name": "atmosphere_moles_of_hydrogen_bromide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_chloride.json b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_chloride.json index 6ffc531e8..132887262 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_chloride.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hydrogen_chloride", + "id": "atmosphere_moles_of_hydrogen_chloride", "type": "standard_name", "name": "atmosphere_moles_of_hydrogen_chloride", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_cyanide.json b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_cyanide.json index 6de7f5650..4899c8f0b 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_cyanide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_cyanide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hydrogen_cyanide", + "id": "atmosphere_moles_of_hydrogen_cyanide", "type": "standard_name", "name": "atmosphere_moles_of_hydrogen_cyanide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_peroxide.json b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_peroxide.json index a057d7361..6f767251b 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_peroxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hydrogen_peroxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hydrogen_peroxide", + "id": "atmosphere_moles_of_hydrogen_peroxide", "type": "standard_name", "name": "atmosphere_moles_of_hydrogen_peroxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hydroperoxyl_radical.json b/data_descriptors/standard_name/atmosphere_moles_of_hydroperoxyl_radical.json index 7eb393163..497dfbb7c 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hydroperoxyl_radical.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hydroperoxyl_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hydroperoxyl_radical", + "id": "atmosphere_moles_of_hydroperoxyl_radical", "type": "standard_name", "name": "atmosphere_moles_of_hydroperoxyl_radical", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for the hydroperoxyl radical is HO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hydroxyl_radical.json b/data_descriptors/standard_name/atmosphere_moles_of_hydroxyl_radical.json index cacf7325a..98404c9b2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hydroxyl_radical.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hydroxyl_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hydroxyl_radical", + "id": "atmosphere_moles_of_hydroxyl_radical", "type": "standard_name", "name": "atmosphere_moles_of_hydroxyl_radical", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hypobromous_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_hypobromous_acid.json index 32a3bf5d8..326bb4421 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hypobromous_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hypobromous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hypobromous_acid", + "id": "atmosphere_moles_of_hypobromous_acid", "type": "standard_name", "name": "atmosphere_moles_of_hypobromous_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_hypochlorous_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_hypochlorous_acid.json index ef09327b8..a6d1e2b14 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_hypochlorous_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_hypochlorous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_hypochlorous_acid", + "id": "atmosphere_moles_of_hypochlorous_acid", "type": "standard_name", "name": "atmosphere_moles_of_hypochlorous_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_inorganic_bromine.json b/data_descriptors/standard_name/atmosphere_moles_of_inorganic_bromine.json index 050d6b80d..6492722d7 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_inorganic_bromine.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_inorganic_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_inorganic_bromine", + "id": "atmosphere_moles_of_inorganic_bromine", "type": "standard_name", "name": "atmosphere_moles_of_inorganic_bromine", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_inorganic_chlorine.json b/data_descriptors/standard_name/atmosphere_moles_of_inorganic_chlorine.json index 12d68c8c2..b766f43f1 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_inorganic_chlorine.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_inorganic_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_inorganic_chlorine", + "id": "atmosphere_moles_of_inorganic_chlorine", "type": "standard_name", "name": "atmosphere_moles_of_inorganic_chlorine", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. \"Inorganic chlorine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"clox\" are used for quantities that contain all inorganic chlorine species except HCl and ClONO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_isoprene.json b/data_descriptors/standard_name/atmosphere_moles_of_isoprene.json index fb1c535ee..bfe2a4932 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_isoprene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_isoprene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_isoprene", + "id": "atmosphere_moles_of_isoprene", "type": "standard_name", "name": "atmosphere_moles_of_isoprene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_limonene.json b/data_descriptors/standard_name/atmosphere_moles_of_limonene.json index 8fc08768b..15617ba55 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_limonene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_limonene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_limonene", + "id": "atmosphere_moles_of_limonene", "type": "standard_name", "name": "atmosphere_moles_of_limonene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_methane.json b/data_descriptors/standard_name/atmosphere_moles_of_methane.json index a63cd40ef..e03c59cb2 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_methane.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_methane", + "id": "atmosphere_moles_of_methane", "type": "standard_name", "name": "atmosphere_moles_of_methane", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_methanol.json b/data_descriptors/standard_name/atmosphere_moles_of_methanol.json index 638e6f8f7..6dccc47ad 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_methanol.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_methanol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_methanol", + "id": "atmosphere_moles_of_methanol", "type": "standard_name", "name": "atmosphere_moles_of_methanol", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_methyl_bromide.json b/data_descriptors/standard_name/atmosphere_moles_of_methyl_bromide.json index b3c3f1016..0864c1661 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_methyl_bromide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_methyl_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_methyl_bromide", + "id": "atmosphere_moles_of_methyl_bromide", "type": "standard_name", "name": "atmosphere_moles_of_methyl_bromide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_methyl_chloride.json b/data_descriptors/standard_name/atmosphere_moles_of_methyl_chloride.json index 3df1fa90a..5245e8d4e 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_methyl_chloride.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_methyl_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_methyl_chloride", + "id": "atmosphere_moles_of_methyl_chloride", "type": "standard_name", "name": "atmosphere_moles_of_methyl_chloride", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_methyl_hydroperoxide.json b/data_descriptors/standard_name/atmosphere_moles_of_methyl_hydroperoxide.json index 5d3036cd9..465b283e6 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_methyl_hydroperoxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_methyl_hydroperoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_methyl_hydroperoxide", + "id": "atmosphere_moles_of_methyl_hydroperoxide", "type": "standard_name", "name": "atmosphere_moles_of_methyl_hydroperoxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_methyl_peroxy_radical.json b/data_descriptors/standard_name/atmosphere_moles_of_methyl_peroxy_radical.json index d3e472e44..be743100a 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_methyl_peroxy_radical.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_methyl_peroxy_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_methyl_peroxy_radical", + "id": "atmosphere_moles_of_methyl_peroxy_radical", "type": "standard_name", "name": "atmosphere_moles_of_methyl_peroxy_radical", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl_peroxy_radical is CH3O2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_molecular_hydrogen.json b/data_descriptors/standard_name/atmosphere_moles_of_molecular_hydrogen.json index 7f9114b3b..c5d30415d 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_molecular_hydrogen.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_molecular_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_molecular_hydrogen", + "id": "atmosphere_moles_of_molecular_hydrogen", "type": "standard_name", "name": "atmosphere_moles_of_molecular_hydrogen", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitrate_radical.json b/data_descriptors/standard_name/atmosphere_moles_of_nitrate_radical.json index 081ec1ea3..23dea97e9 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitrate_radical.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitrate_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitrate_radical", + "id": "atmosphere_moles_of_nitrate_radical", "type": "standard_name", "name": "atmosphere_moles_of_nitrate_radical", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid.json index b1e042463..056b89599 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitric_acid", + "id": "atmosphere_moles_of_nitric_acid", "type": "standard_name", "name": "atmosphere_moles_of_nitric_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json index 7d8337d5d..efebed6b8 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles", + "id": "atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The chemical formula for nitric acid is HNO3. Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_dioxide.json b/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_dioxide.json index 79704697a..8a985a4e4 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitrogen_dioxide", + "id": "atmosphere_moles_of_nitrogen_dioxide", "type": "standard_name", "name": "atmosphere_moles_of_nitrogen_dioxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_monoxide.json b/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_monoxide.json index 6fe86381c..c092eeb03 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_monoxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitrogen_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitrogen_monoxide", + "id": "atmosphere_moles_of_nitrogen_monoxide", "type": "standard_name", "name": "atmosphere_moles_of_nitrogen_monoxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitrous_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_nitrous_acid.json index d62c6858e..502627072 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitrous_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitrous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitrous_acid", + "id": "atmosphere_moles_of_nitrous_acid", "type": "standard_name", "name": "atmosphere_moles_of_nitrous_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nitrous_oxide.json b/data_descriptors/standard_name/atmosphere_moles_of_nitrous_oxide.json index befab487e..f22e7cd0f 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nitrous_oxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nitrous_oxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nitrous_oxide", + "id": "atmosphere_moles_of_nitrous_oxide", "type": "standard_name", "name": "atmosphere_moles_of_nitrous_oxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/atmosphere_moles_of_nmvoc_expressed_as_carbon.json index 05ba76fd9..65bede004 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nmvoc_expressed_as_carbon", + "id": "atmosphere_moles_of_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "atmosphere_moles_of_nmvoc_expressed_as_carbon", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_nox_expressed_as_nitrogen.json b/data_descriptors/standard_name/atmosphere_moles_of_nox_expressed_as_nitrogen.json index 924785282..c546fc4f7 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_nox_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_nox_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_nox_expressed_as_nitrogen", + "id": "atmosphere_moles_of_nox_expressed_as_nitrogen", "type": "standard_name", "name": "atmosphere_moles_of_nox_expressed_as_nitrogen", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_noy_expressed_as_nitrogen.json b/data_descriptors/standard_name/atmosphere_moles_of_noy_expressed_as_nitrogen.json index fed6e762a..7a0685497 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_noy_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_noy_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_noy_expressed_as_nitrogen", + "id": "atmosphere_moles_of_noy_expressed_as_nitrogen", "type": "standard_name", "name": "atmosphere_moles_of_noy_expressed_as_nitrogen", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_ozone.json b/data_descriptors/standard_name/atmosphere_moles_of_ozone.json index 852cbc353..f080a8603 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_ozone.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_ozone", + "id": "atmosphere_moles_of_ozone", "type": "standard_name", "name": "atmosphere_moles_of_ozone", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ozone is O3.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_peroxyacetyl_nitrate.json b/data_descriptors/standard_name/atmosphere_moles_of_peroxyacetyl_nitrate.json index 8e6ceefd4..19a6befb1 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_peroxyacetyl_nitrate.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_peroxyacetyl_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_peroxyacetyl_nitrate", + "id": "atmosphere_moles_of_peroxyacetyl_nitrate", "type": "standard_name", "name": "atmosphere_moles_of_peroxyacetyl_nitrate", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl_nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_peroxynitric_acid.json b/data_descriptors/standard_name/atmosphere_moles_of_peroxynitric_acid.json index 9ac110d02..71d931c2b 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_peroxynitric_acid.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_peroxynitric_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_peroxynitric_acid", + "id": "atmosphere_moles_of_peroxynitric_acid", "type": "standard_name", "name": "atmosphere_moles_of_peroxynitric_acid", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_propane.json b/data_descriptors/standard_name/atmosphere_moles_of_propane.json index 55f4dee42..7a409163a 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_propane.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_propane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_propane", + "id": "atmosphere_moles_of_propane", "type": "standard_name", "name": "atmosphere_moles_of_propane", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_propene.json b/data_descriptors/standard_name/atmosphere_moles_of_propene.json index fd5232165..9495087ab 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_propene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_propene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_propene", + "id": "atmosphere_moles_of_propene", "type": "standard_name", "name": "atmosphere_moles_of_propene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_radon.json b/data_descriptors/standard_name/atmosphere_moles_of_radon.json index 4ec4e43b6..ce715ede8 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_radon.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_radon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_radon", + "id": "atmosphere_moles_of_radon", "type": "standard_name", "name": "atmosphere_moles_of_radon", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_sulfur_dioxide.json b/data_descriptors/standard_name/atmosphere_moles_of_sulfur_dioxide.json index 70331cb8c..9458bb12a 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_sulfur_dioxide.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_sulfur_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_sulfur_dioxide", + "id": "atmosphere_moles_of_sulfur_dioxide", "type": "standard_name", "name": "atmosphere_moles_of_sulfur_dioxide", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_toluene.json b/data_descriptors/standard_name/atmosphere_moles_of_toluene.json index 7ed9e014d..72d0d480a 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_toluene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_toluene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_toluene", + "id": "atmosphere_moles_of_toluene", "type": "standard_name", "name": "atmosphere_moles_of_toluene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_water_vapor.json b/data_descriptors/standard_name/atmosphere_moles_of_water_vapor.json index 72a0870f7..a01489780 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_water_vapor.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_water_vapor", + "id": "atmosphere_moles_of_water_vapor", "type": "standard_name", "name": "atmosphere_moles_of_water_vapor", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe.", diff --git a/data_descriptors/standard_name/atmosphere_moles_of_xylene.json b/data_descriptors/standard_name/atmosphere_moles_of_xylene.json index b91e4fcbc..91aa9c9c6 100644 --- a/data_descriptors/standard_name/atmosphere_moles_of_xylene.json +++ b/data_descriptors/standard_name/atmosphere_moles_of_xylene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_moles_of_xylene", + "id": "atmosphere_moles_of_xylene", "type": "standard_name", "name": "atmosphere_moles_of_xylene", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/atmosphere_momentum_diffusivity.json b/data_descriptors/standard_name/atmosphere_momentum_diffusivity.json index 96bbd481a..3c75f46ae 100644 --- a/data_descriptors/standard_name/atmosphere_momentum_diffusivity.json +++ b/data_descriptors/standard_name/atmosphere_momentum_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_momentum_diffusivity", + "id": "atmosphere_momentum_diffusivity", "type": "standard_name", "name": "atmosphere_momentum_diffusivity", "description": null, diff --git a/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_longwave_energy.json b/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_longwave_energy.json index 9ebe89a31..871eb2bd4 100644 --- a/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_longwave_energy.json +++ b/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_longwave_energy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_net_rate_of_absorption_of_longwave_energy", + "id": "atmosphere_net_rate_of_absorption_of_longwave_energy", "type": "standard_name", "name": "atmosphere_net_rate_of_absorption_of_longwave_energy", "description": "\"longwave\" means longwave radiation. Net absorbed radiation is the difference between absorbed and emitted radiation.", diff --git a/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_shortwave_energy.json b/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_shortwave_energy.json index d53033b1f..8404e0aa6 100644 --- a/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_shortwave_energy.json +++ b/data_descriptors/standard_name/atmosphere_net_rate_of_absorption_of_shortwave_energy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_net_rate_of_absorption_of_shortwave_energy", + "id": "atmosphere_net_rate_of_absorption_of_shortwave_energy", "type": "standard_name", "name": "atmosphere_net_rate_of_absorption_of_shortwave_energy", "description": "\"shortwave\" means shortwave radiation. Net absorbed radiation is the difference between absorbed and emitted radiation.", diff --git a/data_descriptors/standard_name/atmosphere_net_upward_convective_mass_flux.json b/data_descriptors/standard_name/atmosphere_net_upward_convective_mass_flux.json index 6dba26d17..d3c773900 100644 --- a/data_descriptors/standard_name/atmosphere_net_upward_convective_mass_flux.json +++ b/data_descriptors/standard_name/atmosphere_net_upward_convective_mass_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_net_upward_convective_mass_flux", + "id": "atmosphere_net_upward_convective_mass_flux", "type": "standard_name", "name": "atmosphere_net_upward_convective_mass_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The atmosphere convective mass flux is the vertical transport of mass for a field of cumulus clouds or thermals, given by the product of air density and vertical velocity. Net upward convective mass flux is the difference between the updraft mass flux and the downdraft mass flux. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). For an area-average, cell_methods should specify whether the average is over all the area or the area of updrafts and/or downdrafts only.", diff --git a/data_descriptors/standard_name/atmosphere_net_upward_deep_convective_mass_flux.json b/data_descriptors/standard_name/atmosphere_net_upward_deep_convective_mass_flux.json index 541abe86d..3ac36ab7d 100644 --- a/data_descriptors/standard_name/atmosphere_net_upward_deep_convective_mass_flux.json +++ b/data_descriptors/standard_name/atmosphere_net_upward_deep_convective_mass_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_net_upward_deep_convective_mass_flux", + "id": "atmosphere_net_upward_deep_convective_mass_flux", "type": "standard_name", "name": "atmosphere_net_upward_deep_convective_mass_flux", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The atmosphere convective mass flux is the vertical transport of mass for a field of cumulus clouds or thermals, given by the product of air density and vertical velocity. For an area-average, cell_methods should specify whether the average is over all the area or the area of updrafts and/or downdrafts only. Net upward convective mass flux is the difference between the updraft mass flux and the downdraft mass flux.", diff --git a/data_descriptors/standard_name/atmosphere_net_upward_shallow_convective_mass_flux.json b/data_descriptors/standard_name/atmosphere_net_upward_shallow_convective_mass_flux.json index 3e5635385..fc603edb1 100644 --- a/data_descriptors/standard_name/atmosphere_net_upward_shallow_convective_mass_flux.json +++ b/data_descriptors/standard_name/atmosphere_net_upward_shallow_convective_mass_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_net_upward_shallow_convective_mass_flux", + "id": "atmosphere_net_upward_shallow_convective_mass_flux", "type": "standard_name", "name": "atmosphere_net_upward_shallow_convective_mass_flux", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The atmosphere convective mass flux is the vertical transport of mass for a field of cumulus clouds or thermals, given by the product of air density and vertical velocity. For an area-average, cell_methods should specify whether the average is over all the area or the area of updrafts and/or downdrafts only. Net upward convective mass flux is the difference between the updraft mass flux and the downdraft mass flux.", diff --git a/data_descriptors/standard_name/atmosphere_northward_stress_due_to_gravity_wave_drag.json b/data_descriptors/standard_name/atmosphere_northward_stress_due_to_gravity_wave_drag.json index eece5f340..c693edac4 100644 --- a/data_descriptors/standard_name/atmosphere_northward_stress_due_to_gravity_wave_drag.json +++ b/data_descriptors/standard_name/atmosphere_northward_stress_due_to_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_northward_stress_due_to_gravity_wave_drag", + "id": "atmosphere_northward_stress_due_to_gravity_wave_drag", "type": "standard_name", "name": "atmosphere_northward_stress_due_to_gravity_wave_drag", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Atmosphere_Xward_stress is a stress which tends to accelerate the atmosphere in direction X.", diff --git a/data_descriptors/standard_name/atmosphere_number_content_of_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_number_content_of_aerosol_particles.json index 91847d2c6..632dc068f 100644 --- a/data_descriptors/standard_name/atmosphere_number_content_of_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_number_content_of_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_number_content_of_aerosol_particles", + "id": "atmosphere_number_content_of_aerosol_particles", "type": "standard_name", "name": "atmosphere_number_content_of_aerosol_particles", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself.", diff --git a/data_descriptors/standard_name/atmosphere_number_content_of_cloud_droplets.json b/data_descriptors/standard_name/atmosphere_number_content_of_cloud_droplets.json index 8ece593a2..8c7490dce 100644 --- a/data_descriptors/standard_name/atmosphere_number_content_of_cloud_droplets.json +++ b/data_descriptors/standard_name/atmosphere_number_content_of_cloud_droplets.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_number_content_of_cloud_droplets", + "id": "atmosphere_number_content_of_cloud_droplets", "type": "standard_name", "name": "atmosphere_number_content_of_cloud_droplets", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_number_content_of_ice_crystals.json b/data_descriptors/standard_name/atmosphere_number_content_of_ice_crystals.json index ea687abb7..424596061 100644 --- a/data_descriptors/standard_name/atmosphere_number_content_of_ice_crystals.json +++ b/data_descriptors/standard_name/atmosphere_number_content_of_ice_crystals.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_number_content_of_ice_crystals", + "id": "atmosphere_number_content_of_ice_crystals", "type": "standard_name", "name": "atmosphere_number_content_of_ice_crystals", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/atmosphere_obukhov_length.json b/data_descriptors/standard_name/atmosphere_obukhov_length.json index 7857e481d..cdfae6ad3 100644 --- a/data_descriptors/standard_name/atmosphere_obukhov_length.json +++ b/data_descriptors/standard_name/atmosphere_obukhov_length.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_obukhov_length", + "id": "atmosphere_obukhov_length", "type": "standard_name", "name": "atmosphere_obukhov_length", "description": "The height in the atmosphere, L, that buoyant production or destruction of turbulent energy balances the shear production of turbulent kinetic energy: L = -u*3 / (kB0), where u* is the wind frictional velocity, k is the von Karman constant, and B0 is the atmospheric surface buoyancy flux. If the buoyancy flux is destabilizing, L is negative.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ambient_aerosol_particles.json index 25c226a07..4ad0f2ce2 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles.json index ba4ee02d2..1ca3d4e11 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_ammonium_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol.json index a96cc6beb..c6b08109b 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol", + "id": "atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. \"Aerosol\" means the suspended liquid or solid particles in air (except cloud droplets). \"Ambient aerosol\" is aerosol that has taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol. Black carbon aerosol is composed of elemental carbon. It is strongly light absorbing.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_cloud.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_cloud.json index 526655f92..767dec7a2 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_cloud.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_cloud", + "id": "atmosphere_optical_thickness_due_to_cloud", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_cloud", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. \"Cloud\" means the component of extinction owing to the presence of liquid or ice water particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_convective_cloud.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_convective_cloud.json index 105df4581..b87f7965d 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_convective_cloud.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_convective_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_convective_cloud", + "id": "atmosphere_optical_thickness_due_to_convective_cloud", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_convective_cloud", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. Convective cloud is that produced by the convection schemes in an atmosphere model. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles.json index 3a3118980..80c90a34f 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles.json index e37a25d6f..345223202 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_dust_dry_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json index 5f76612a1..d804a30f9 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json index 46398cf8e..480890427 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles.json index 39ba097db..c7074761a 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_pm10_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles.json index 552cb5e25..226e2699e 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles.json index a761292a6..36af155ac 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json index f3aae2f75..9cf03d76b 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_stratiform_cloud.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_stratiform_cloud.json index d0fe07074..f1e5cd013 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_stratiform_cloud.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_stratiform_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_stratiform_cloud", + "id": "atmosphere_optical_thickness_due_to_stratiform_cloud", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_stratiform_cloud", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json index d5de5f84f..5e3398c1d 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles.json b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles.json index 542cbd70f..db9cb3ce0 100644 --- a/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles", + "id": "atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles", "type": "standard_name", "name": "atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"atmosphere_optical_thickness_due_to_water_in_ambient_aerosol\" refers to the optical thickness due to the water that is associated with aerosol particles due to hygroscopic growth in ambient air, affecting the radius and refractive index of the particle. It corresponds to the difference between the total dry aerosol optical thickness and the total ambient aerosol optical thickness. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/atmosphere_potential_energy_content.json b/data_descriptors/standard_name/atmosphere_potential_energy_content.json index 7f132203d..d6cdbc8e4 100644 --- a/data_descriptors/standard_name/atmosphere_potential_energy_content.json +++ b/data_descriptors/standard_name/atmosphere_potential_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_potential_energy_content", + "id": "atmosphere_potential_energy_content", "type": "standard_name", "name": "atmosphere_potential_energy_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/atmosphere_sigma_coordinate.json b/data_descriptors/standard_name/atmosphere_sigma_coordinate.json index 84aa107ee..e4ed94cda 100644 --- a/data_descriptors/standard_name/atmosphere_sigma_coordinate.json +++ b/data_descriptors/standard_name/atmosphere_sigma_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_sigma_coordinate", + "id": "atmosphere_sigma_coordinate", "type": "standard_name", "name": "atmosphere_sigma_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/atmosphere_sleve_coordinate.json b/data_descriptors/standard_name/atmosphere_sleve_coordinate.json index 4d8a138f0..bf6f8124c 100644 --- a/data_descriptors/standard_name/atmosphere_sleve_coordinate.json +++ b/data_descriptors/standard_name/atmosphere_sleve_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_sleve_coordinate", + "id": "atmosphere_sleve_coordinate", "type": "standard_name", "name": "atmosphere_sleve_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/atmosphere_stability_k_index.json b/data_descriptors/standard_name/atmosphere_stability_k_index.json index 77beb42b1..0146dd800 100644 --- a/data_descriptors/standard_name/atmosphere_stability_k_index.json +++ b/data_descriptors/standard_name/atmosphere_stability_k_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_stability_k_index", + "id": "atmosphere_stability_k_index", "type": "standard_name", "name": "atmosphere_stability_k_index", "description": "The atmosphere_stability_k_index is an index that indicates the potential of severe convection and is often referred to as simply the k index. The index is calculated as A + B - C, where A is the difference in air temperature between 850 and 500 hPa, B is the dew point temperature at 850 hPa, and C is the dew point depression (i.e. the amount by which the air temperature exceeds its dew point temperature) at 700 hPa. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/atmosphere_stability_showalter_index.json b/data_descriptors/standard_name/atmosphere_stability_showalter_index.json index d84113702..360c7bba5 100644 --- a/data_descriptors/standard_name/atmosphere_stability_showalter_index.json +++ b/data_descriptors/standard_name/atmosphere_stability_showalter_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_stability_showalter_index", + "id": "atmosphere_stability_showalter_index", "type": "standard_name", "name": "atmosphere_stability_showalter_index", "description": "The atmosphere_stability_showalter_index is an index used to determine convective and thunderstorm potential and is often referred to as simply the showalter index. The index is defined as the temperature difference between a parcel of air lifted from 850 to 500 hPa (wet adiabatically) and the ambient air temperature at 500 hPa. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/atmosphere_stability_total_totals_index.json b/data_descriptors/standard_name/atmosphere_stability_total_totals_index.json index 7036155a7..74f6b335d 100644 --- a/data_descriptors/standard_name/atmosphere_stability_total_totals_index.json +++ b/data_descriptors/standard_name/atmosphere_stability_total_totals_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_stability_total_totals_index", + "id": "atmosphere_stability_total_totals_index", "type": "standard_name", "name": "atmosphere_stability_total_totals_index", "description": "The atmosphere_stability_total_totals_index indicates thelikelihood of severe convection and is often referred to as simply thetotal totals index. The index is derived from the difference in airtemperature between 850 and 500 hPa (the vertical totals) and thedifference between the dew point temperature at 850 hPa and the airtemperature at 500 hPa (the cross totals). The vertical totals and crosstotals are summed to obtain the index. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction.json b/data_descriptors/standard_name/atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction.json index cb0f72cc8..b31dae130 100644 --- a/data_descriptors/standard_name/atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction.json +++ b/data_descriptors/standard_name/atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction", + "id": "atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction", "type": "standard_name", "name": "atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction", "description": "The \"meridional mass streamfunction\" is a streamfunction of the zonally averaged mass transport in the meridional plane. The \"Transformed Eulerian Mean\" refers to a formulation of the mean equations which incorporates some eddy terms into the definition of the mean, described in Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", diff --git a/data_descriptors/standard_name/atmosphere_updraft_convective_mass_flux.json b/data_descriptors/standard_name/atmosphere_updraft_convective_mass_flux.json index da0be8cc3..4ec8e0eb1 100644 --- a/data_descriptors/standard_name/atmosphere_updraft_convective_mass_flux.json +++ b/data_descriptors/standard_name/atmosphere_updraft_convective_mass_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_updraft_convective_mass_flux", + "id": "atmosphere_updraft_convective_mass_flux", "type": "standard_name", "name": "atmosphere_updraft_convective_mass_flux", "description": "The atmosphere convective mass flux is the vertical transport of mass for a field of cumulus clouds or thermals, given by the product of air density and vertical velocity. For an area-average, cell_methods should specify whether the average is over all the area or the area of updrafts and/or downdrafts only. \"Updraft\" means that the flux is positive in the updward direction (negative downward). upward. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/atmosphere_upward_absolute_vorticity.json b/data_descriptors/standard_name/atmosphere_upward_absolute_vorticity.json index becb98221..91a1dd395 100644 --- a/data_descriptors/standard_name/atmosphere_upward_absolute_vorticity.json +++ b/data_descriptors/standard_name/atmosphere_upward_absolute_vorticity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_upward_absolute_vorticity", + "id": "atmosphere_upward_absolute_vorticity", "type": "standard_name", "name": "atmosphere_upward_absolute_vorticity", "description": "Atmosphere upward absolute vorticity is the sum of the atmosphere upward relative vorticity and the vertical component of vorticity due to the Earth\u2019s rotation. In contrast, the quantity with standard name atmosphere_upward_relative_vorticity excludes the Earth's rotation. Vorticity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). A positive value of atmosphere_upward_absolute_vorticity indicates anticlockwise rotation when viewed from above.", diff --git a/data_descriptors/standard_name/atmosphere_upward_relative_vorticity.json b/data_descriptors/standard_name/atmosphere_upward_relative_vorticity.json index ec7f9dbae..7b4ae63d1 100644 --- a/data_descriptors/standard_name/atmosphere_upward_relative_vorticity.json +++ b/data_descriptors/standard_name/atmosphere_upward_relative_vorticity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_upward_relative_vorticity", + "id": "atmosphere_upward_relative_vorticity", "type": "standard_name", "name": "atmosphere_upward_relative_vorticity", "description": "Atmosphere upward relative vorticity is the vertical component of the 3D air vorticity vector. The vertical component arises from horizontal velocity only. \"Relative\" in this context means the vorticity of the air relative to the rotating solid earth reference frame, i.e. excluding the Earth's own rotation. In contrast, the quantity with standard name atmosphere_upward_absolute_vorticity includes the Earth's rotation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). A positive value of atmosphere_upward_relative_vorticity indicates anticlockwise rotation when viewed from above.", diff --git a/data_descriptors/standard_name/atmosphere_x_relative_vorticity.json b/data_descriptors/standard_name/atmosphere_x_relative_vorticity.json index b1f32049b..da48f3836 100644 --- a/data_descriptors/standard_name/atmosphere_x_relative_vorticity.json +++ b/data_descriptors/standard_name/atmosphere_x_relative_vorticity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_x_relative_vorticity", + "id": "atmosphere_x_relative_vorticity", "type": "standard_name", "name": "atmosphere_x_relative_vorticity", "description": "Atmosphere x relative vorticity is the x component of the 3D air vorticity vector. \"Relative\" in this context means the vorticity of the air relative to the rotating solid earth reference frame, i.e. excluding the Earth's own rotation. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. A positive value of atmosphere_x_relative_vorticity indicates anticlockwise rotation when viewed by an observer looking along the axis in the direction of decreasing x, i.e. consistent with the \"right hand screw\" rule.", diff --git a/data_descriptors/standard_name/atmosphere_y_relative_vorticity.json b/data_descriptors/standard_name/atmosphere_y_relative_vorticity.json index a98c5fe35..e5d043677 100644 --- a/data_descriptors/standard_name/atmosphere_y_relative_vorticity.json +++ b/data_descriptors/standard_name/atmosphere_y_relative_vorticity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/atmosphere_y_relative_vorticity", + "id": "atmosphere_y_relative_vorticity", "type": "standard_name", "name": "atmosphere_y_relative_vorticity", "description": "Atmosphere y relative vorticity is the y component of the 3D air vorticity vector. \"Relative\" in this context means the vorticity of the air relative to the rotating solid earth reference frame, i.e. excluding the Earth's own rotation. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. A positive value of atmosphere_y_relative_vorticity indicates anticlockwise rotation when viewed by an observer looking along the axis in the direction of decreasing y, i.e. consistent with the \"right hand screw\" rule.", diff --git a/data_descriptors/standard_name/attenuated_signal_test_quality_flag.json b/data_descriptors/standard_name/attenuated_signal_test_quality_flag.json index c81215363..447ba60d1 100644 --- a/data_descriptors/standard_name/attenuated_signal_test_quality_flag.json +++ b/data_descriptors/standard_name/attenuated_signal_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/attenuated_signal_test_quality_flag", + "id": "attenuated_signal_test_quality_flag", "type": "standard_name", "name": "attenuated_signal_test_quality_flag", "description": "A quality flag that reports the result of the Attenuated Signal test, which checks for near-flat-line conditions using a range or standard deviation. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/automated_tropical_cyclone_forecasting_system_storm_identifier.json b/data_descriptors/standard_name/automated_tropical_cyclone_forecasting_system_storm_identifier.json index 4b1f8bf59..65e35f319 100644 --- a/data_descriptors/standard_name/automated_tropical_cyclone_forecasting_system_storm_identifier.json +++ b/data_descriptors/standard_name/automated_tropical_cyclone_forecasting_system_storm_identifier.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/automated_tropical_cyclone_forecasting_system_storm_identifier", + "id": "automated_tropical_cyclone_forecasting_system_storm_identifier", "type": "standard_name", "name": "automated_tropical_cyclone_forecasting_system_storm_identifier", "description": "The Automated Tropical Cyclone Forecasting System (ATCF) storm identifier is an 8 character string which identifies a tropical cyclone. The storm identifier has the form BBCCYYYY, where BB is the ocean basin, specifically: AL - North Atlantic basin, north of the Equator; SL - South Atlantic basin, south of the Equator; EP - North East Pacific basin, eastward of 140 degrees west longitude; CP - North Central Pacific basin, between the dateline and 140 degrees west longitude; WP - North West Pacific basin, westward of the dateline; IO - North Indian Ocean basin, north of the Equator between 40 and 100 degrees east longitude; SH - South Pacific Ocean basin and South Indian Ocean basin. CC is the cyclone number. Numbers 01 through 49 are reserved for tropical and subtropical cyclones. A cyclone number is assigned to each tropical or subtropical cyclone in each basin as it develops. Numbers are assigned in chronological order. Numbers 50 through 79 are reserved for internal use by operational forecast centers. Numbers 80 through 89 are reserved for training, exercises and testing. Numbers 90 through 99 are reserved for tropical disturbances having the potential to become tropical or subtropical cyclones. The 90's are assigned sequentially and reused throughout the calendar year. YYYY is the four-digit year. This is calendar year for the northern hemisphere. For the southern hemisphere, the year begins July 1, with calendar year plus one. Reference: Miller, R.J., Schrader, A.J., Sampson, C.R., & Tsui, T.L. (1990), The Automated Tropical Cyclone Forecasting System (ATCF), American Meteorological Society Computer Techniques, 5, 653 - 660.", diff --git a/data_descriptors/standard_name/backscattering_ratio_in_air.json b/data_descriptors/standard_name/backscattering_ratio_in_air.json index 84259198e..6de269fcb 100644 --- a/data_descriptors/standard_name/backscattering_ratio_in_air.json +++ b/data_descriptors/standard_name/backscattering_ratio_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/backscattering_ratio_in_air", + "id": "backscattering_ratio_in_air", "type": "standard_name", "name": "backscattering_ratio_in_air", "description": "Scattering of radiation is its deflection from its incident path without loss of energy. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity. \"Backscattering ratio\" is the ratio of the quantity with standard name volume_attenuated_backwards_scattering_function_in_air to the quantity with standard name volume_attenuated_backwards_scattering_function_in_air_assuming_no_aerosol_or_cloud.", diff --git a/data_descriptors/standard_name/baroclinic_eastward_sea_water_velocity.json b/data_descriptors/standard_name/baroclinic_eastward_sea_water_velocity.json index 2266f3355..07e093845 100644 --- a/data_descriptors/standard_name/baroclinic_eastward_sea_water_velocity.json +++ b/data_descriptors/standard_name/baroclinic_eastward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/baroclinic_eastward_sea_water_velocity", + "id": "baroclinic_eastward_sea_water_velocity", "type": "standard_name", "name": "baroclinic_eastward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward).", diff --git a/data_descriptors/standard_name/baroclinic_northward_sea_water_velocity.json b/data_descriptors/standard_name/baroclinic_northward_sea_water_velocity.json index fb242b314..f7d46b6c6 100644 --- a/data_descriptors/standard_name/baroclinic_northward_sea_water_velocity.json +++ b/data_descriptors/standard_name/baroclinic_northward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/baroclinic_northward_sea_water_velocity", + "id": "baroclinic_northward_sea_water_velocity", "type": "standard_name", "name": "baroclinic_northward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward).", diff --git a/data_descriptors/standard_name/barometric_altitude.json b/data_descriptors/standard_name/barometric_altitude.json index ff2a551af..f58f79a4e 100644 --- a/data_descriptors/standard_name/barometric_altitude.json +++ b/data_descriptors/standard_name/barometric_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/barometric_altitude", + "id": "barometric_altitude", "type": "standard_name", "name": "barometric_altitude", "description": "Barometric altitude is the altitude determined by a pressure measurement which is converted to altitude through interpolation of the International Standard Atmosphere (ICAO, 1976). A mean sea level pressure of 1013.25 hPa is used for the surface pressure.", diff --git a/data_descriptors/standard_name/barotropic_eastward_sea_water_velocity.json b/data_descriptors/standard_name/barotropic_eastward_sea_water_velocity.json index 893827096..3551f1cb0 100644 --- a/data_descriptors/standard_name/barotropic_eastward_sea_water_velocity.json +++ b/data_descriptors/standard_name/barotropic_eastward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/barotropic_eastward_sea_water_velocity", + "id": "barotropic_eastward_sea_water_velocity", "type": "standard_name", "name": "barotropic_eastward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward).", diff --git a/data_descriptors/standard_name/barotropic_northward_sea_water_velocity.json b/data_descriptors/standard_name/barotropic_northward_sea_water_velocity.json index d8bd37183..8a5477e16 100644 --- a/data_descriptors/standard_name/barotropic_northward_sea_water_velocity.json +++ b/data_descriptors/standard_name/barotropic_northward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/barotropic_northward_sea_water_velocity", + "id": "barotropic_northward_sea_water_velocity", "type": "standard_name", "name": "barotropic_northward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward).", diff --git a/data_descriptors/standard_name/barotropic_sea_water_x_velocity.json b/data_descriptors/standard_name/barotropic_sea_water_x_velocity.json index 49f33ed35..aae1c1317 100644 --- a/data_descriptors/standard_name/barotropic_sea_water_x_velocity.json +++ b/data_descriptors/standard_name/barotropic_sea_water_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/barotropic_sea_water_x_velocity", + "id": "barotropic_sea_water_x_velocity", "type": "standard_name", "name": "barotropic_sea_water_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x.", diff --git a/data_descriptors/standard_name/barotropic_sea_water_y_velocity.json b/data_descriptors/standard_name/barotropic_sea_water_y_velocity.json index 9b736a651..6409b69ad 100644 --- a/data_descriptors/standard_name/barotropic_sea_water_y_velocity.json +++ b/data_descriptors/standard_name/barotropic_sea_water_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/barotropic_sea_water_y_velocity", + "id": "barotropic_sea_water_y_velocity", "type": "standard_name", "name": "barotropic_sea_water_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y.", diff --git a/data_descriptors/standard_name/basal_downward_heat_flux_in_sea_ice.json b/data_descriptors/standard_name/basal_downward_heat_flux_in_sea_ice.json index 789e35004..d4662dabc 100644 --- a/data_descriptors/standard_name/basal_downward_heat_flux_in_sea_ice.json +++ b/data_descriptors/standard_name/basal_downward_heat_flux_in_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/basal_downward_heat_flux_in_sea_ice", + "id": "basal_downward_heat_flux_in_sea_ice", "type": "standard_name", "name": "basal_downward_heat_flux_in_sea_ice", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/baseflow_amount.json b/data_descriptors/standard_name/baseflow_amount.json index 998e27ffa..2b6bbce81 100644 --- a/data_descriptors/standard_name/baseflow_amount.json +++ b/data_descriptors/standard_name/baseflow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/baseflow_amount", + "id": "baseflow_amount", "type": "standard_name", "name": "baseflow_amount", "description": "\"Baseflow\" is subsurface runoff which takes place below the level of the water table. Runoff is the liquid water which drains from land. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json b/data_descriptors/standard_name/beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json index 8930e3ad3..b284c45e7 100644 --- a/data_descriptors/standard_name/beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json +++ b/data_descriptors/standard_name/beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water", + "id": "beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water", "type": "standard_name", "name": "beam_consistency_indicator_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water", "description": "The \"beam_consistency_indicator\" is the degree to which the received acoustic pulse is correlated with the transmitted pulse. It is used as a data quality assessment parameter in ADCP (acoustic doppler current profiler) instruments and is frequently referred to as \"correlation magnitude\". Convention is that the larger the value, the higher the signal to noise ratio and therefore the better the quality of the current vector measurements; the maximum value of the indicator is 128.", diff --git a/data_descriptors/standard_name/beaufort_wind_force.json b/data_descriptors/standard_name/beaufort_wind_force.json index 4db9fed1f..1ad194ea6 100644 --- a/data_descriptors/standard_name/beaufort_wind_force.json +++ b/data_descriptors/standard_name/beaufort_wind_force.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/beaufort_wind_force", + "id": "beaufort_wind_force", "type": "standard_name", "name": "beaufort_wind_force", "description": "\"Beaufort wind force\" is an index assigned on the Beaufort wind force scale and relates a qualitative description of the degree of disturbance or destruction caused by wind to the speed of the wind. The Beaufort wind scale varies between 0 (qualitatively described as calm, smoke rises vertically, sea appears glassy) (wind speeds in the range 0 - 0.2 m s-1) and 12 (hurricane, wave heights in excess of 14 m) (wind speeds in excess of 32.7 m s-1).", diff --git a/data_descriptors/standard_name/bedrock_altitude.json b/data_descriptors/standard_name/bedrock_altitude.json index 911728f1a..601caac34 100644 --- a/data_descriptors/standard_name/bedrock_altitude.json +++ b/data_descriptors/standard_name/bedrock_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/bedrock_altitude", + "id": "bedrock_altitude", "type": "standard_name", "name": "bedrock_altitude", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. \"Bedrock\" is the solid Earth surface beneath land ice, ocean water or soil.", diff --git a/data_descriptors/standard_name/bedrock_altitude_change_due_to_isostatic_adjustment.json b/data_descriptors/standard_name/bedrock_altitude_change_due_to_isostatic_adjustment.json index 3d62f4afd..d05074dfe 100644 --- a/data_descriptors/standard_name/bedrock_altitude_change_due_to_isostatic_adjustment.json +++ b/data_descriptors/standard_name/bedrock_altitude_change_due_to_isostatic_adjustment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/bedrock_altitude_change_due_to_isostatic_adjustment", + "id": "bedrock_altitude_change_due_to_isostatic_adjustment", "type": "standard_name", "name": "bedrock_altitude_change_due_to_isostatic_adjustment", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. \"Bedrock\" is the solid Earth surface beneath land ice, ocean water or soil. The zero of bedrock altitude change is arbitrary. Isostatic adjustment is the vertical movement of the lithosphere due to changing surface ice and water loads.", diff --git a/data_descriptors/standard_name/bedrock_depth_below_ground_level.json b/data_descriptors/standard_name/bedrock_depth_below_ground_level.json index b63cd2ac7..ccb571b74 100644 --- a/data_descriptors/standard_name/bedrock_depth_below_ground_level.json +++ b/data_descriptors/standard_name/bedrock_depth_below_ground_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/bedrock_depth_below_ground_level", + "id": "bedrock_depth_below_ground_level", "type": "standard_name", "name": "bedrock_depth_below_ground_level", "description": "The bedrock_depth_below_ground_level is the vertical distance between the ground and the bedrock. \"Bedrock\" refers to the surface of the consolidated rock, beneath any unconsolidated rock, sediment, soil, water or land ice. \"Ground level\" means the level of the solid surface in land areas without permanent inland water, beneath any snow, ice or surface water.", diff --git a/data_descriptors/standard_name/biological_taxon_lsid.json b/data_descriptors/standard_name/biological_taxon_lsid.json index 73c2785cc..a67e54782 100644 --- a/data_descriptors/standard_name/biological_taxon_lsid.json +++ b/data_descriptors/standard_name/biological_taxon_lsid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/biological_taxon_lsid", + "id": "biological_taxon_lsid", "type": "standard_name", "name": "biological_taxon_lsid", "description": "\"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. The quantity with standard name biological_taxon_lsid is the machine-readable identifier based on a taxon registration system using the syntax convention specified for the Life Science Identifier (LSID) - urn:lsid:::[:]. This includes the reference classification in the element and these are restricted by the LSID governance. It is strongly recommended in CF that the authority chosen is World Register of Marine Species (WoRMS) for oceanographic data and Integrated Taxonomic Information System (ITIS) for freshwater and terrestrial data. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables. This identifier is a narrower equivalent to the scientificNameID field in the Darwin Core Standard.", diff --git a/data_descriptors/standard_name/biological_taxon_name.json b/data_descriptors/standard_name/biological_taxon_name.json index b2330d1fe..57f3264cf 100644 --- a/data_descriptors/standard_name/biological_taxon_name.json +++ b/data_descriptors/standard_name/biological_taxon_name.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/biological_taxon_name", + "id": "biological_taxon_name", "type": "standard_name", "name": "biological_taxon_name", "description": "\"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. The quantity with standard name biological_taxon_name is the human-readable label for the taxon such as Calanus finmarchicus. The label should be registered in either WoRMS (http://www.marinespecies.org) or ITIS (https://www.itis.gov/) and spelled exactly as registered. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/bioluminescent_photon_rate_in_sea_water.json b/data_descriptors/standard_name/bioluminescent_photon_rate_in_sea_water.json index 54de605a5..adf967b2f 100644 --- a/data_descriptors/standard_name/bioluminescent_photon_rate_in_sea_water.json +++ b/data_descriptors/standard_name/bioluminescent_photon_rate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/bioluminescent_photon_rate_in_sea_water", + "id": "bioluminescent_photon_rate_in_sea_water", "type": "standard_name", "name": "bioluminescent_photon_rate_in_sea_water", "description": null, diff --git a/data_descriptors/standard_name/biomass_burning_carbon_flux.json b/data_descriptors/standard_name/biomass_burning_carbon_flux.json index c714cdd20..4dde61cdc 100644 --- a/data_descriptors/standard_name/biomass_burning_carbon_flux.json +++ b/data_descriptors/standard_name/biomass_burning_carbon_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/biomass_burning_carbon_flux", + "id": "biomass_burning_carbon_flux", "type": "standard_name", "name": "biomass_burning_carbon_flux", "description": "\"Biomass burning carbon\" refers to the rate at which biomass is burned by forest fires etc., expressed as the mass of carbon which it contains. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/brightness_temperature.json b/data_descriptors/standard_name/brightness_temperature.json index 247917fff..b093202eb 100644 --- a/data_descriptors/standard_name/brightness_temperature.json +++ b/data_descriptors/standard_name/brightness_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/brightness_temperature", + "id": "brightness_temperature", "type": "standard_name", "name": "brightness_temperature", "description": "The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units)..", diff --git a/data_descriptors/standard_name/brightness_temperature_anomaly.json b/data_descriptors/standard_name/brightness_temperature_anomaly.json index 11eb3833a..d5965157f 100644 --- a/data_descriptors/standard_name/brightness_temperature_anomaly.json +++ b/data_descriptors/standard_name/brightness_temperature_anomaly.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/brightness_temperature_anomaly", + "id": "brightness_temperature_anomaly", "type": "standard_name", "name": "brightness_temperature_anomaly", "description": "The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. \"anomaly\" means difference from climatology. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/brightness_temperature_at_cloud_top.json b/data_descriptors/standard_name/brightness_temperature_at_cloud_top.json index f62e6dc78..9f5c86caf 100644 --- a/data_descriptors/standard_name/brightness_temperature_at_cloud_top.json +++ b/data_descriptors/standard_name/brightness_temperature_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/brightness_temperature_at_cloud_top", + "id": "brightness_temperature_at_cloud_top", "type": "standard_name", "name": "brightness_temperature_at_cloud_top", "description": "cloud_top refers to the top of the highest cloud. brightness_temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. A coordinate variable of radiation_wavelength, sensor_band_central_radiation_wavelength, or radiation_frequency may be specified to indicate that the brightness temperature applies at specific wavelengths or frequencies. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/brunt_vaisala_frequency_in_air.json b/data_descriptors/standard_name/brunt_vaisala_frequency_in_air.json index 4d56fbbc2..2ca3dc4ef 100644 --- a/data_descriptors/standard_name/brunt_vaisala_frequency_in_air.json +++ b/data_descriptors/standard_name/brunt_vaisala_frequency_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/brunt_vaisala_frequency_in_air", + "id": "brunt_vaisala_frequency_in_air", "type": "standard_name", "name": "brunt_vaisala_frequency_in_air", "description": "Frequency is the number of oscillations of a wave per unit time. Brunt-Vaisala frequency is also sometimes called \"buoyancy frequency\" and is a measure of the vertical stratification of the medium.", diff --git a/data_descriptors/standard_name/burned_area.json b/data_descriptors/standard_name/burned_area.json index 836c8ba14..762825118 100644 --- a/data_descriptors/standard_name/burned_area.json +++ b/data_descriptors/standard_name/burned_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/burned_area", + "id": "burned_area", "type": "standard_name", "name": "burned_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\". \"Burned area\" means the area of burned vegetation.", diff --git a/data_descriptors/standard_name/burned_area_fraction.json b/data_descriptors/standard_name/burned_area_fraction.json index 4b87a74b6..f89c03182 100644 --- a/data_descriptors/standard_name/burned_area_fraction.json +++ b/data_descriptors/standard_name/burned_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/burned_area_fraction", + "id": "burned_area_fraction", "type": "standard_name", "name": "burned_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Burned area\" means the area of burned vegetation.", diff --git a/data_descriptors/standard_name/canadian_fire_weather_index.json b/data_descriptors/standard_name/canadian_fire_weather_index.json index 70b76aa1a..63ec086b4 100644 --- a/data_descriptors/standard_name/canadian_fire_weather_index.json +++ b/data_descriptors/standard_name/canadian_fire_weather_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canadian_fire_weather_index", + "id": "canadian_fire_weather_index", "type": "standard_name", "name": "canadian_fire_weather_index", "description": "The Canadian Fire Weather Index (CFWI) is a numerical rating of potential frontal fire intensity from the Canadian Forest Fire Index System. It indicates fire intensity by combining the rate of spread with the amount of fuel being consumed and is also used for general public information about fire danger conditions. It is a function of wind speed, temperature, relative humidity, and precipitation. The calculation accounts for multiple layers of flammable material on the ground as well as fine fuels above the surface, combined with the expected rate of spread of fire. The index is open ended.", diff --git a/data_descriptors/standard_name/canopy_albedo.json b/data_descriptors/standard_name/canopy_albedo.json index befcdb372..5189716ac 100644 --- a/data_descriptors/standard_name/canopy_albedo.json +++ b/data_descriptors/standard_name/canopy_albedo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_albedo", + "id": "canopy_albedo", "type": "standard_name", "name": "canopy_albedo", "description": "Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy. The surface_albedo restricted to the area type \"vegetation\" is related to canopy_albedo, but the former also includes the effect of radiation being reflected from the ground underneath the canopy.", diff --git a/data_descriptors/standard_name/canopy_and_surface_water_amount.json b/data_descriptors/standard_name/canopy_and_surface_water_amount.json index 6e2eca9d1..6f20423a4 100644 --- a/data_descriptors/standard_name/canopy_and_surface_water_amount.json +++ b/data_descriptors/standard_name/canopy_and_surface_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_and_surface_water_amount", + "id": "canopy_and_surface_water_amount", "type": "standard_name", "name": "canopy_and_surface_water_amount", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Amount\" means mass per unit area. \"Water\" means water in all phases, including frozen i.e. ice and snow. \"Canopy and surface water\" means the sum of water on the ground and on the canopy. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/canopy_height.json b/data_descriptors/standard_name/canopy_height.json index 0e23b343f..56ebadc44 100644 --- a/data_descriptors/standard_name/canopy_height.json +++ b/data_descriptors/standard_name/canopy_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_height", + "id": "canopy_height", "type": "standard_name", "name": "canopy_height", "description": "Height is the vertical distance above the surface. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/canopy_resistance_to_ozone_dry_deposition.json b/data_descriptors/standard_name/canopy_resistance_to_ozone_dry_deposition.json index 272a7c55d..e9049132a 100644 --- a/data_descriptors/standard_name/canopy_resistance_to_ozone_dry_deposition.json +++ b/data_descriptors/standard_name/canopy_resistance_to_ozone_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_resistance_to_ozone_dry_deposition", + "id": "canopy_resistance_to_ozone_dry_deposition", "type": "standard_name", "name": "canopy_resistance_to_ozone_dry_deposition", "description": "\"Canopy\" means the plant or vegetation canopy. The \"canopy_resistance\" is the resistance of a compound to uptake by the vegetation canopy. It varies both with the surface and the chemical species or physical state (gas or particle). Canopy resistance is a function of the canopy stomatal resistance (Rstom), the canopy cuticle resistance (Rcuticle), and the soil resistance (Rsoil). In the case of ozone the uptake by the cuticle is small compared to the uptake through the stomata. Reference: Kerstiens and Lendzian, 1989. This means that the cuticle transfer pathway can be neglected in model parameterizations. Reference: Ganzeveld and Jos Lelieveld , 1995, doi/10.1029/95JD02266/pdf. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/canopy_snow_amount.json b/data_descriptors/standard_name/canopy_snow_amount.json index 844aad376..e6d7b2205 100644 --- a/data_descriptors/standard_name/canopy_snow_amount.json +++ b/data_descriptors/standard_name/canopy_snow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_snow_amount", + "id": "canopy_snow_amount", "type": "standard_name", "name": "canopy_snow_amount", "description": "\"Amount\" means mass per unit area. The phrase \"canopy_snow\" means snow lying on the canopy. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/canopy_temperature.json b/data_descriptors/standard_name/canopy_temperature.json index e5e329499..094711003 100644 --- a/data_descriptors/standard_name/canopy_temperature.json +++ b/data_descriptors/standard_name/canopy_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_temperature", + "id": "canopy_temperature", "type": "standard_name", "name": "canopy_temperature", "description": "\"Canopy temperature\" is the bulk temperature of the canopy, not the surface (skin) temperature. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/canopy_throughfall_flux.json b/data_descriptors/standard_name/canopy_throughfall_flux.json index 45ebb18d0..602a7464a 100644 --- a/data_descriptors/standard_name/canopy_throughfall_flux.json +++ b/data_descriptors/standard_name/canopy_throughfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_throughfall_flux", + "id": "canopy_throughfall_flux", "type": "standard_name", "name": "canopy_throughfall_flux", "description": "\"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy. \"Throughfall\" is the part of the precipitation flux that reaches the ground directly through the vegetative canopy, through spaces in the canopy, and as drip from the leaves, twigs, and stems (but not including snowmelt). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/canopy_water_amount.json b/data_descriptors/standard_name/canopy_water_amount.json index dd07518f5..a79bc01de 100644 --- a/data_descriptors/standard_name/canopy_water_amount.json +++ b/data_descriptors/standard_name/canopy_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/canopy_water_amount", + "id": "canopy_water_amount", "type": "standard_name", "name": "canopy_water_amount", "description": "\"Amount\" means mass per unit area. \"Water\" means water in all phases, including frozen i.e. ice and snow. The canopy water is the water on the canopy. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/carbon_mass_content_of_forestry_and_agricultural_products.json b/data_descriptors/standard_name/carbon_mass_content_of_forestry_and_agricultural_products.json index 80b41e36c..b1ea7fe0a 100644 --- a/data_descriptors/standard_name/carbon_mass_content_of_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/carbon_mass_content_of_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/carbon_mass_content_of_forestry_and_agricultural_products", + "id": "carbon_mass_content_of_forestry_and_agricultural_products", "type": "standard_name", "name": "carbon_mass_content_of_forestry_and_agricultural_products", "description": "\"Content\" indicates a quantity per unit area. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites.", diff --git a/data_descriptors/standard_name/carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json b/data_descriptors/standard_name/carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json index bbaa3c27d..70364fc57 100644 --- a/data_descriptors/standard_name/carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json +++ b/data_descriptors/standard_name/carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", + "id": "carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "type": "standard_name", "name": "carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Anthropogenic\" means influenced, caused, or created by human activity. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change.json b/data_descriptors/standard_name/carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change.json index 953505ccf..3cf62e526 100644 --- a/data_descriptors/standard_name/carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change.json +++ b/data_descriptors/standard_name/carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change", + "id": "carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change", "type": "standard_name", "name": "carbon_mass_flux_into_litter_and_soil_due_to_anthropogenic_land_use_or_land_cover_change", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Litter\" is dead plant material in or above the soil. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Anthropogenic\" means influenced, caused, or created by human activity. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_litter.json b/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_litter.json index 994798dbc..5f5385f7d 100644 --- a/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_litter.json +++ b/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_litter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/carbon_mass_flux_into_soil_from_litter", + "id": "carbon_mass_flux_into_soil_from_litter", "type": "standard_name", "name": "carbon_mass_flux_into_soil_from_litter", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Litter\" is dead plant material in or above the soil.", diff --git a/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_vegetation_excluding_litter.json b/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_vegetation_excluding_litter.json index 2871947b4..7939d4418 100644 --- a/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_vegetation_excluding_litter.json +++ b/data_descriptors/standard_name/carbon_mass_flux_into_soil_from_vegetation_excluding_litter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/carbon_mass_flux_into_soil_from_vegetation_excluding_litter", + "id": "carbon_mass_flux_into_soil_from_vegetation_excluding_litter", "type": "standard_name", "name": "carbon_mass_flux_into_soil_from_vegetation_excluding_litter", "description": "\"Vegetation\" means any plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/carbon_mass_transport_in_river_channel.json b/data_descriptors/standard_name/carbon_mass_transport_in_river_channel.json index dfd3c7102..adc58f0a1 100644 --- a/data_descriptors/standard_name/carbon_mass_transport_in_river_channel.json +++ b/data_descriptors/standard_name/carbon_mass_transport_in_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/carbon_mass_transport_in_river_channel", + "id": "carbon_mass_transport_in_river_channel", "type": "standard_name", "name": "carbon_mass_transport_in_river_channel", "description": "The amount of total carbon mass transported in the river channels from land into the ocean. This quantity can be provided at a certain location within the river network and floodplain (over land) or at the river mouth (over ocean) where the river enters the ocean. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/cell_area.json b/data_descriptors/standard_name/cell_area.json index 4ed16f4b7..0f6c08e89 100644 --- a/data_descriptors/standard_name/cell_area.json +++ b/data_descriptors/standard_name/cell_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cell_area", + "id": "cell_area", "type": "standard_name", "name": "cell_area", "description": "\"Cell_area\" is the horizontal area of a gridcell.", diff --git a/data_descriptors/standard_name/cell_thickness.json b/data_descriptors/standard_name/cell_thickness.json index effbd08c7..4c92eff57 100644 --- a/data_descriptors/standard_name/cell_thickness.json +++ b/data_descriptors/standard_name/cell_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cell_thickness", + "id": "cell_thickness", "type": "standard_name", "name": "cell_thickness", "description": "\"Thickness\" means the vertical extent of a layer. \"Cell\" refers to a model grid-cell.", diff --git a/data_descriptors/standard_name/change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json b/data_descriptors/standard_name/change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json index 75215fde0..1e9728c9a 100644 --- a/data_descriptors/standard_name/change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json +++ b/data_descriptors/standard_name/change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure", + "id": "change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure", "type": "standard_name", "name": "change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"wrt\" means with respect to. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Atmosphere energy content\" has not yet been precisely defined! Please express your views on this quantity on the CF email list. See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json b/data_descriptors/standard_name/change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json index 673c2b43c..16e9740c2 100644 --- a/data_descriptors/standard_name/change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json +++ b/data_descriptors/standard_name/change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure", + "id": "change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure", "type": "standard_name", "name": "change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The abbreviation \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/change_in_land_ice_amount.json b/data_descriptors/standard_name/change_in_land_ice_amount.json index 55988db3f..f1f3a1ee5 100644 --- a/data_descriptors/standard_name/change_in_land_ice_amount.json +++ b/data_descriptors/standard_name/change_in_land_ice_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_land_ice_amount", + "id": "change_in_land_ice_amount", "type": "standard_name", "name": "change_in_land_ice_amount", "description": "\"Amount\" means mass per unit area. Zero change in land ice amount is an arbitrary level. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/change_in_land_ice_mass.json b/data_descriptors/standard_name/change_in_land_ice_mass.json index 9516e94d8..0586b4f9f 100644 --- a/data_descriptors/standard_name/change_in_land_ice_mass.json +++ b/data_descriptors/standard_name/change_in_land_ice_mass.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_land_ice_mass", + "id": "change_in_land_ice_mass", "type": "standard_name", "name": "change_in_land_ice_mass", "description": "Zero change in land ice mass is an arbitrary level. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The horizontal domain over which the quantity is calculated is described by the associated coordinate variables and coordinate bounds or by a coordinate variable or scalar coordinate variable with the standard name of \"region\" supplied according to section 6.1.1 of the CF conventions.", diff --git a/data_descriptors/standard_name/change_in_mean_sea_level_wrt_solid_surface.json b/data_descriptors/standard_name/change_in_mean_sea_level_wrt_solid_surface.json index 0cd533e72..d3cb6fea9 100644 --- a/data_descriptors/standard_name/change_in_mean_sea_level_wrt_solid_surface.json +++ b/data_descriptors/standard_name/change_in_mean_sea_level_wrt_solid_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_mean_sea_level_wrt_solid_surface", + "id": "change_in_mean_sea_level_wrt_solid_surface", "type": "standard_name", "name": "change_in_mean_sea_level_wrt_solid_surface", "description": "The change in local mean sea level relative to the local solid surface, i.e. sea floor. The abbreviation \"wrt\" means \"with respect to\". A positive value means sea level rise.", diff --git a/data_descriptors/standard_name/change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading.json b/data_descriptors/standard_name/change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading.json index 8e0312c2f..8f54f6087 100644 --- a/data_descriptors/standard_name/change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading.json +++ b/data_descriptors/standard_name/change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading", + "id": "change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading", "type": "standard_name", "name": "change_in_sea_floor_height_above_reference_ellipsoid_due_to_ocean_tide_loading", "description": "Sea surface height is a time-varying quantity. A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are a significant contributor to the observed sea surface height. The load tidal component of sea surface height describes the variability of the sea surface due to the deformation of the Earth because of the weight of the water masses displaced by ocean tides.", diff --git a/data_descriptors/standard_name/change_in_sea_surface_height_due_to_change_in_air_pressure.json b/data_descriptors/standard_name/change_in_sea_surface_height_due_to_change_in_air_pressure.json index e3bc6ef39..27c04317f 100644 --- a/data_descriptors/standard_name/change_in_sea_surface_height_due_to_change_in_air_pressure.json +++ b/data_descriptors/standard_name/change_in_sea_surface_height_due_to_change_in_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_in_sea_surface_height_due_to_change_in_air_pressure", + "id": "change_in_sea_surface_height_due_to_change_in_air_pressure", "type": "standard_name", "name": "change_in_sea_surface_height_due_to_change_in_air_pressure", "description": "Sea surface height is a time-varying quantity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/change_over_time_in_amount_of_ice_and_snow_on_land.json b/data_descriptors/standard_name/change_over_time_in_amount_of_ice_and_snow_on_land.json index 56e258769..374364352 100644 --- a/data_descriptors/standard_name/change_over_time_in_amount_of_ice_and_snow_on_land.json +++ b/data_descriptors/standard_name/change_over_time_in_amount_of_ice_and_snow_on_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_amount_of_ice_and_snow_on_land", + "id": "change_over_time_in_amount_of_ice_and_snow_on_land", "type": "standard_name", "name": "change_over_time_in_amount_of_ice_and_snow_on_land", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Amount\" means mass per unit area. The phrase \"ice_and_snow_on_land\" means ice in glaciers, ice caps, ice sheets and shelves, river and lake ice, any other ice on a land surface, such as frozen flood water, and snow lying on such ice or on the land surface.", diff --git a/data_descriptors/standard_name/change_over_time_in_atmosphere_mass_content_of_water_due_to_advection.json b/data_descriptors/standard_name/change_over_time_in_atmosphere_mass_content_of_water_due_to_advection.json index 353d84d77..738a4d85c 100644 --- a/data_descriptors/standard_name/change_over_time_in_atmosphere_mass_content_of_water_due_to_advection.json +++ b/data_descriptors/standard_name/change_over_time_in_atmosphere_mass_content_of_water_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_atmosphere_mass_content_of_water_due_to_advection", + "id": "change_over_time_in_atmosphere_mass_content_of_water_due_to_advection", "type": "standard_name", "name": "change_over_time_in_atmosphere_mass_content_of_water_due_to_advection", "description": "\"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Water\" means water in all phases. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/change_over_time_in_canopy_water_amount.json b/data_descriptors/standard_name/change_over_time_in_canopy_water_amount.json index c67f788b4..c9ceb4b8e 100644 --- a/data_descriptors/standard_name/change_over_time_in_canopy_water_amount.json +++ b/data_descriptors/standard_name/change_over_time_in_canopy_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_canopy_water_amount", + "id": "change_over_time_in_canopy_water_amount", "type": "standard_name", "name": "change_over_time_in_canopy_water_amount", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. Canopy water is the water on the canopy. \"Water\" means water in all phases, including frozen, i.e. ice and snow. \"Amount\" means mass per unit area. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/change_over_time_in_groundwater_amount.json b/data_descriptors/standard_name/change_over_time_in_groundwater_amount.json index 10dd958ea..03013eb8d 100644 --- a/data_descriptors/standard_name/change_over_time_in_groundwater_amount.json +++ b/data_descriptors/standard_name/change_over_time_in_groundwater_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_groundwater_amount", + "id": "change_over_time_in_groundwater_amount", "type": "standard_name", "name": "change_over_time_in_groundwater_amount", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Water\" means water in all phases. Groundwater is subsurface water below the depth of the water table. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/change_over_time_in_land_surface_liquid_water_amount.json b/data_descriptors/standard_name/change_over_time_in_land_surface_liquid_water_amount.json index 3764d8018..2c4657f17 100644 --- a/data_descriptors/standard_name/change_over_time_in_land_surface_liquid_water_amount.json +++ b/data_descriptors/standard_name/change_over_time_in_land_surface_liquid_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_land_surface_liquid_water_amount", + "id": "change_over_time_in_land_surface_liquid_water_amount", "type": "standard_name", "name": "change_over_time_in_land_surface_liquid_water_amount", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. The surface called \"surface\" means the lower boundary of the atmosphere. \"Amount\" means mass per unit area. \"Land surface liquid water amount\" includes water in rivers, wetlands, lakes, reservoirs and liquid precipitation intercepted by the vegetation canopy.", diff --git a/data_descriptors/standard_name/change_over_time_in_land_water_amount.json b/data_descriptors/standard_name/change_over_time_in_land_water_amount.json index e6a93fa59..b54ab6373 100644 --- a/data_descriptors/standard_name/change_over_time_in_land_water_amount.json +++ b/data_descriptors/standard_name/change_over_time_in_land_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_land_water_amount", + "id": "change_over_time_in_land_water_amount", "type": "standard_name", "name": "change_over_time_in_land_water_amount", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Amount\" means mass per unit area. \"Water\" means water in all phases. The phrase \"land_water_amount\", often known as \"Terrestrial Water Storage\", includes: surface liquid water (water in rivers, wetlands, lakes, reservoirs, rainfall intercepted by the canopy); surface ice and snow (glaciers, ice caps, grounded ice sheets not displacing sea water, river and lake ice, other surface ice such as frozen flood water, snow lying on the surface and intercepted by the canopy); subsurface water (liquid and frozen soil water, groundwater).", diff --git a/data_descriptors/standard_name/change_over_time_in_mass_content_of_water_in_soil.json b/data_descriptors/standard_name/change_over_time_in_mass_content_of_water_in_soil.json index 9140603bc..fbbb70dc3 100644 --- a/data_descriptors/standard_name/change_over_time_in_mass_content_of_water_in_soil.json +++ b/data_descriptors/standard_name/change_over_time_in_mass_content_of_water_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_mass_content_of_water_in_soil", + "id": "change_over_time_in_mass_content_of_water_in_soil", "type": "standard_name", "name": "change_over_time_in_mass_content_of_water_in_soil", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Content\" indicates a quantity per unit area. The mass content of water in soil refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/change_over_time_in_river_water_amount.json b/data_descriptors/standard_name/change_over_time_in_river_water_amount.json index df1901c46..80b42ae3f 100644 --- a/data_descriptors/standard_name/change_over_time_in_river_water_amount.json +++ b/data_descriptors/standard_name/change_over_time_in_river_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_river_water_amount", + "id": "change_over_time_in_river_water_amount", "type": "standard_name", "name": "change_over_time_in_river_water_amount", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Water\" means water in all phases. \"River\" refers to the water in the fluvial system (stream and floodplain). \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_absolute_salinity.json b/data_descriptors/standard_name/change_over_time_in_sea_water_absolute_salinity.json index 9c57f18c2..e2e356c87 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_absolute_salinity.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_absolute_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_absolute_salinity", + "id": "change_over_time_in_sea_water_absolute_salinity", "type": "standard_name", "name": "change_over_time_in_sea_water_absolute_salinity", "description": "\"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. Absolute Salinity, S_A, is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the Intergovernmental Oceanographic Commission (IOC). It is the mass fraction of dissolved material in sea water. Absolute Salinity incorporates the spatial variations in the composition of sea water. This type of Absolute Salinity is also called \"Density Salinity\". TEOS-10 estimates Absolute Salinity as the salinity variable that, when used with the TEOS-10 expression for density, yields the correct density of a sea water sample even when the sample is not of Reference Composition. In practice, Absolute Salinity is often calculated from Practical Salinity using a spatial lookup table of pre-defined values of the Absolute Salinity Anomaly. It is recommended that the version of (TEOS-10) software and the associated Absolute Salinity Anomaly climatology be specified within metadata by attaching a comment attribute to the data variable. Reference: www.teos-10.org; Millero et al., 2008 doi: 10.1016/j.dsr.2007.10.001. There are also standard names for the precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 onwards), sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_conservative_temperature.json b/data_descriptors/standard_name/change_over_time_in_sea_water_conservative_temperature.json index ce72aeaa2..ec33ded54 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_conservative_temperature.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_conservative_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_conservative_temperature", + "id": "change_over_time_in_sea_water_conservative_temperature", "type": "standard_name", "name": "change_over_time_in_sea_water_conservative_temperature", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_density.json b/data_descriptors/standard_name/change_over_time_in_sea_water_density.json index 5dfc5b792..37901102e 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_density.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_density", + "id": "change_over_time_in_sea_water_density", "type": "standard_name", "name": "change_over_time_in_sea_water_density", "description": "Sea water density is the in-situ density (not the potential density). If 1000 kg m-3 is subtracted, the standard name \"sea_water_sigma_t\" should be chosen instead. \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_neutral_density.json b/data_descriptors/standard_name/change_over_time_in_sea_water_neutral_density.json index 667b50d36..96f6daed9 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_neutral_density.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_neutral_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_neutral_density", + "id": "change_over_time_in_sea_water_neutral_density", "type": "standard_name", "name": "change_over_time_in_sea_water_neutral_density", "description": "\"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Neutral density\" is a variable designed so that a surface of constant neutral density everywhere has a local slope that is close to the local slope of the neutral tangent plane. At the sea surface in the equatorial Pacific neutral density is very close to the potential density anomaly. At other locations, this is not the case. For example, along a neutral density surface there is a difference of up to 0.14 kg/m^3 in the potential density anomaly at the outcrops in the Southern and Northern hemispheres. Refer to Jackett & McDougall (1997; Journal of Physical Oceanography, Vol 27, doi: 10.1175/1520-0485(1997)027<0237:ANDVFT>2.0.CO;2) for more information.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_potential_density.json b/data_descriptors/standard_name/change_over_time_in_sea_water_potential_density.json index a3c0c14c1..46442ce8a 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_potential_density.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_potential_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_potential_density", + "id": "change_over_time_in_sea_water_potential_density", "type": "standard_name", "name": "change_over_time_in_sea_water_potential_density", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time interval, which should be defined by the bounds of the time coordinate. Sea water potential density is the density a parcel of sea water would have if moved adiabatically to a reference pressure, by default assumed to be sea level pressure. To specify the reference pressure to which the quantity applies, provide a scalar coordinate variable with standard name reference_pressure. The density of a substance is its mass per unit volume. For sea water potential density, if 1000 kg m-3 is subtracted, the standard name \"sea_water_sigma_theta\" should be chosen instead.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_potential_temperature.json b/data_descriptors/standard_name/change_over_time_in_sea_water_potential_temperature.json index 4ad5a1dd7..994320c6e 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_potential_temperature.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_potential_temperature", + "id": "change_over_time_in_sea_water_potential_temperature", "type": "standard_name", "name": "change_over_time_in_sea_water_potential_temperature", "description": "Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_practical_salinity.json b/data_descriptors/standard_name/change_over_time_in_sea_water_practical_salinity.json index 0ada969f2..4283ea607 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_practical_salinity.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_practical_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_practical_salinity", + "id": "change_over_time_in_sea_water_practical_salinity", "type": "standard_name", "name": "change_over_time_in_sea_water_practical_salinity", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time interval, which should be defined by the bounds of the time coordinate. Practical Salinity, S_P, is a determination of the salinity of sea water, based on its electrical conductance. The measured conductance, corrected for temperature and pressure, is compared to the conductance of a standard potassium chloride solution, producing a value on the Practical Salinity Scale of 1978 (PSS-78). This name should not be used to describe salinity observations made before 1978, or ones not based on conductance measurements. Conversion of Practical Salinity to other precisely defined salinity measures should use the appropriate formulas specified by TEOS-10. Other standard names for precisely defined salinity quantities are sea_water_absolute_salinity (S_A); sea_water_preformed_salinity (S_*), sea_water_reference_salinity (S_R); sea_water_cox_salinity (S_C), used for salinity observations between 1967 and 1977; and sea_water_knudsen_salinity (S_K), used for salinity observations between 1901 and 1966. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity. Reference: www.teos-10.org; Lewis, 1980 doi:10.1109/JOE.1980.1145448.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_preformed_salinity.json b/data_descriptors/standard_name/change_over_time_in_sea_water_preformed_salinity.json index bedefb30d..9b0523bac 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_preformed_salinity.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_preformed_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_preformed_salinity", + "id": "change_over_time_in_sea_water_preformed_salinity", "type": "standard_name", "name": "change_over_time_in_sea_water_preformed_salinity", "description": "\"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. Preformed Salinity, S*, is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the Intergovernmental Oceanographic Commission (IOC). Preformed Salinity is a salinity variable that is designed to be as conservative as possible, by removing the estimated biogeochemical influences on the sea water composition. Preformed Salinity is Absolute Salinity, S_A (which has the standard name sea_water_absolute_salinity), minus all contributions to sea water composition from biogeochemical processes. Preformed Salinity is the mass fraction of dissolved material in sea water. Reference: www.teos-10.org; Pawlowicz et al., 2011 doi: 10.5194/os-7-363-2011; Wright et al., 2011 doi: 10.5194/os-7-1-2011. There are also standard names for the precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 onwards), and sea_water_reference_salinity. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_salinity.json b/data_descriptors/standard_name/change_over_time_in_sea_water_salinity.json index 78f7bc24d..763fb4fb9 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_salinity.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_salinity", + "id": "change_over_time_in_sea_water_salinity", "type": "standard_name", "name": "change_over_time_in_sea_water_salinity", "description": "\"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_specific_potential_enthalpy.json b/data_descriptors/standard_name/change_over_time_in_sea_water_specific_potential_enthalpy.json index b729e70ff..8f2f3ab10 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_specific_potential_enthalpy.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_specific_potential_enthalpy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_specific_potential_enthalpy", + "id": "change_over_time_in_sea_water_specific_potential_enthalpy", "type": "standard_name", "name": "change_over_time_in_sea_water_specific_potential_enthalpy", "description": "\"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. The potential enthalpy of a sea water parcel is the specific enthalpy after an adiabatic and isohaline change in pressure from its in situ pressure to the sea pressure p = 0 dbar. \"specific\" means per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2.", diff --git a/data_descriptors/standard_name/change_over_time_in_sea_water_temperature.json b/data_descriptors/standard_name/change_over_time_in_sea_water_temperature.json index 2e76f860b..98a0e9960 100644 --- a/data_descriptors/standard_name/change_over_time_in_sea_water_temperature.json +++ b/data_descriptors/standard_name/change_over_time_in_sea_water_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_sea_water_temperature", + "id": "change_over_time_in_sea_water_temperature", "type": "standard_name", "name": "change_over_time_in_sea_water_temperature", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate.Sea water temperature is the in situ temperature of the sea water. To specify the depth at which the temperature applies use a vertical coordinate variable or scalar coordinate variable. There are standard names for sea_surface_temperature, sea_surface_skin_temperature, sea_surface_subskin_temperature and sea_surface_foundation_temperature which can be used to describe data located at the specified surfaces. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/change_over_time_in_surface_snow_amount.json b/data_descriptors/standard_name/change_over_time_in_surface_snow_amount.json index 6fe0565a4..a85b7ddf8 100644 --- a/data_descriptors/standard_name/change_over_time_in_surface_snow_amount.json +++ b/data_descriptors/standard_name/change_over_time_in_surface_snow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_surface_snow_amount", + "id": "change_over_time_in_surface_snow_amount", "type": "standard_name", "name": "change_over_time_in_surface_snow_amount", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land.json b/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land.json index 9e99b4f5d..2a7c327d6 100644 --- a/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land.json +++ b/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land", + "id": "change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land", "type": "standard_name", "name": "change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. Thermal energy is the total vibrational energy, kinetic and potential, of all the molecules and atoms in a substance. The phrase \"ice_and_snow_on_land\" means ice in glaciers, ice caps, ice sheets and shelves, river and lake ice, any other ice on a land surface, such as frozen flood water, and snow lying on such ice or on the land surface.", diff --git a/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil.json b/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil.json index 7666ff47f..17e3fb130 100644 --- a/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil.json +++ b/data_descriptors/standard_name/change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil", + "id": "change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil", "type": "standard_name", "name": "change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil", "description": "The phrase \"change_over_time_in_X\" means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. \"Content\" indicates a quantity per unit area. Thermal energy is the total vibrational energy, kinetic and potential, of all the molecules and atoms in a substance. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used.", diff --git a/data_descriptors/standard_name/charnock_coefficient_for_surface_roughness_length_for_momentum_in_air.json b/data_descriptors/standard_name/charnock_coefficient_for_surface_roughness_length_for_momentum_in_air.json index 73cac0ce0..00f9f6cdd 100644 --- a/data_descriptors/standard_name/charnock_coefficient_for_surface_roughness_length_for_momentum_in_air.json +++ b/data_descriptors/standard_name/charnock_coefficient_for_surface_roughness_length_for_momentum_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/charnock_coefficient_for_surface_roughness_length_for_momentum_in_air", + "id": "charnock_coefficient_for_surface_roughness_length_for_momentum_in_air", "type": "standard_name", "name": "charnock_coefficient_for_surface_roughness_length_for_momentum_in_air", "description": "Coefficient value, based on the Charnock (1955) empirical expression for deriving the quantity with standard name surface_roughness_length_for_momentum_in_air over the ocean. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Charnock%27s_relation. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/clear_sky_area_fraction.json b/data_descriptors/standard_name/clear_sky_area_fraction.json index 729033898..fccf91b88 100644 --- a/data_descriptors/standard_name/clear_sky_area_fraction.json +++ b/data_descriptors/standard_name/clear_sky_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/clear_sky_area_fraction", + "id": "clear_sky_area_fraction", "type": "standard_name", "name": "clear_sky_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The clear_sky area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/climatology_test_quality_flag.json b/data_descriptors/standard_name/climatology_test_quality_flag.json index c679f26e8..ab58bcb8a 100644 --- a/data_descriptors/standard_name/climatology_test_quality_flag.json +++ b/data_descriptors/standard_name/climatology_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/climatology_test_quality_flag", + "id": "climatology_test_quality_flag", "type": "standard_name", "name": "climatology_test_quality_flag", "description": "A quality flag that reports the result of the Climatology test, which checks that values are within reasonable range bounds for a given time and location. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/cloud_albedo.json b/data_descriptors/standard_name/cloud_albedo.json index 56ce96825..4900202a7 100644 --- a/data_descriptors/standard_name/cloud_albedo.json +++ b/data_descriptors/standard_name/cloud_albedo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_albedo", + "id": "cloud_albedo", "type": "standard_name", "name": "cloud_albedo", "description": "The albedo of cloud. Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum.", diff --git a/data_descriptors/standard_name/cloud_area_fraction.json b/data_descriptors/standard_name/cloud_area_fraction.json index 890b64847..1d145c5cf 100644 --- a/data_descriptors/standard_name/cloud_area_fraction.json +++ b/data_descriptors/standard_name/cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_area_fraction", + "id": "cloud_area_fraction", "type": "standard_name", "name": "cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names also exist for high, medium and low cloud types. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/cloud_area_fraction_in_atmosphere_layer.json b/data_descriptors/standard_name/cloud_area_fraction_in_atmosphere_layer.json index 9119626e8..c89a6102f 100644 --- a/data_descriptors/standard_name/cloud_area_fraction_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/cloud_area_fraction_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_area_fraction_in_atmosphere_layer", + "id": "cloud_area_fraction_in_atmosphere_layer", "type": "standard_name", "name": "cloud_area_fraction_in_atmosphere_layer", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Standard names also exist for high, medium and low cloud types. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/cloud_base_altitude.json b/data_descriptors/standard_name/cloud_base_altitude.json index 30ad144fb..18157063d 100644 --- a/data_descriptors/standard_name/cloud_base_altitude.json +++ b/data_descriptors/standard_name/cloud_base_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_base_altitude", + "id": "cloud_base_altitude", "type": "standard_name", "name": "cloud_base_altitude", "description": "cloud_base refers to the base of the lowest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/cloud_binary_mask.json b/data_descriptors/standard_name/cloud_binary_mask.json index dad353af0..65a6715b7 100644 --- a/data_descriptors/standard_name/cloud_binary_mask.json +++ b/data_descriptors/standard_name/cloud_binary_mask.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_binary_mask", + "id": "cloud_binary_mask", "type": "standard_name", "name": "cloud_binary_mask", "description": "X_binary_mask has 1 where condition X is met, 0 elsewhere. 1 = cloud present, 0 = cloud absent (clear). If no threshold is supplied, the binary mask is 1 if there is any non-zero amount of cloud. if a threshold is supplied, it should be specified by associating a coordinate variable or scalar coordinate variable with the data variable and giving the coordinate variable a standard name of cloud_area_fraction. The values of the coordinate variable are the threshold values for the corresponding subarrays of the data variable.", diff --git a/data_descriptors/standard_name/cloud_ice_mixing_ratio.json b/data_descriptors/standard_name/cloud_ice_mixing_ratio.json index 8183d7a93..9e82dfd81 100644 --- a/data_descriptors/standard_name/cloud_ice_mixing_ratio.json +++ b/data_descriptors/standard_name/cloud_ice_mixing_ratio.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_ice_mixing_ratio", + "id": "cloud_ice_mixing_ratio", "type": "standard_name", "name": "cloud_ice_mixing_ratio", "description": "Cloud ice mixing ratio of a parcel of air is the ratio of the mass of ice to the mass of dry air.", diff --git a/data_descriptors/standard_name/cloud_liquid_water_mixing_ratio.json b/data_descriptors/standard_name/cloud_liquid_water_mixing_ratio.json index a9452e8b3..c02516e4c 100644 --- a/data_descriptors/standard_name/cloud_liquid_water_mixing_ratio.json +++ b/data_descriptors/standard_name/cloud_liquid_water_mixing_ratio.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_liquid_water_mixing_ratio", + "id": "cloud_liquid_water_mixing_ratio", "type": "standard_name", "name": "cloud_liquid_water_mixing_ratio", "description": "Cloud liquid water mixing ratio of a parcel of air is the ratio of the mass of liquid water to the mass of dry air. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/cloud_top_altitude.json b/data_descriptors/standard_name/cloud_top_altitude.json index 759c4c6d1..90a39c335 100644 --- a/data_descriptors/standard_name/cloud_top_altitude.json +++ b/data_descriptors/standard_name/cloud_top_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_top_altitude", + "id": "cloud_top_altitude", "type": "standard_name", "name": "cloud_top_altitude", "description": "cloud_top refers to the top of the highest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/cloud_type.json b/data_descriptors/standard_name/cloud_type.json index ae361c9ad..f242721db 100644 --- a/data_descriptors/standard_name/cloud_type.json +++ b/data_descriptors/standard_name/cloud_type.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/cloud_type", + "id": "cloud_type", "type": "standard_name", "name": "cloud_type", "description": "A variable with the standard_name of cloud_type contains either strings which indicate the cloud type, or flags which can be translated to strings using flag_values and flag_meanings attributes.", diff --git a/data_descriptors/standard_name/colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water.json b/data_descriptors/standard_name/colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water.json index 18983370e..264880462 100644 --- a/data_descriptors/standard_name/colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water.json +++ b/data_descriptors/standard_name/colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water", + "id": "colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water", "type": "standard_name", "name": "colony_forming_unit_number_concentration_of_biological_taxon_in_sea_water", "description": "\"Colony forming unit\" means an estimate of the viable bacterial or fungal numbers determined by counting colonies grown from a sample. \"Number concentration\" means the number of particles or other specified objects per unit volume. \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/compressive_strength_of_sea_ice.json b/data_descriptors/standard_name/compressive_strength_of_sea_ice.json index f220dd335..b99abd576 100644 --- a/data_descriptors/standard_name/compressive_strength_of_sea_ice.json +++ b/data_descriptors/standard_name/compressive_strength_of_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/compressive_strength_of_sea_ice", + "id": "compressive_strength_of_sea_ice", "type": "standard_name", "name": "compressive_strength_of_sea_ice", "description": "\"Compressive strength\" is a measure of the capacity of a material to withstand compressive forces. If compressive forces are exerted on a material in excess of its compressive strength, fracturing will occur. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/compressive_strength_of_unconfined_frozen_soil.json b/data_descriptors/standard_name/compressive_strength_of_unconfined_frozen_soil.json index 06cb56829..9035807e6 100644 --- a/data_descriptors/standard_name/compressive_strength_of_unconfined_frozen_soil.json +++ b/data_descriptors/standard_name/compressive_strength_of_unconfined_frozen_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/compressive_strength_of_unconfined_frozen_soil", + "id": "compressive_strength_of_unconfined_frozen_soil", "type": "standard_name", "name": "compressive_strength_of_unconfined_frozen_soil", "description": "The maximum force applied as axial strain to an unconfined frozen soil sample before failure.", diff --git a/data_descriptors/standard_name/compressive_strength_of_unconfined_soil.json b/data_descriptors/standard_name/compressive_strength_of_unconfined_soil.json index 5be576ddc..7f813cc8a 100644 --- a/data_descriptors/standard_name/compressive_strength_of_unconfined_soil.json +++ b/data_descriptors/standard_name/compressive_strength_of_unconfined_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/compressive_strength_of_unconfined_soil", + "id": "compressive_strength_of_unconfined_soil", "type": "standard_name", "name": "compressive_strength_of_unconfined_soil", "description": "The maximum force applied as axial strain to an unconfined soil sample before failure.", diff --git a/data_descriptors/standard_name/concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate.json b/data_descriptors/standard_name/concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate.json index 50e2aa8fc..fbed3101b 100644 --- a/data_descriptors/standard_name/concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate.json +++ b/data_descriptors/standard_name/concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate", + "id": "concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate", "type": "standard_name", "name": "concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate", "description": "The quantity with standard name concentration_of_colored_dissolved_organic_matter_in_sea_water_expressed_as_equivalent_mass_fraction_of_quinine_sulfate_dihydrate is also commonly known as Chromophoric Dissolved Organic Matter (CDOM). CDOM plays an important role in the carbon cycling and biogeochemistry of coastal waters. It occurs naturally in aquatic environments primarily as a result of tannins released from decaying plant and animal matter, which can enter coastal areas in river run-off containing organic materials leached from soils. When present in high concentrations, it imparts a brown or yellowish color to water. Its presence can negatively impact fish populations by reducing dissolved oxygen concentrations to harmful levels and by releasing nutrients and metals that contaminate the water. Increased understanding of the role of CDOM will further our ability to manage and protect coastal ecosystems. Sensors are commonly calibrated against a 100 parts per billion (ppb) quinine sulfate dihydrate solution, a fluorescent reference standard commonly used with CDOM sensors. CDOM sensors therefore report in \"QSDE\" (quinine sulfate dihydrate equivalents). It is important to note, however, that CDOM concentrations in QSDE are not necessarily equivalent to the in situ CDOM concentrations in ppb.", diff --git a/data_descriptors/standard_name/convection_time_fraction.json b/data_descriptors/standard_name/convection_time_fraction.json index 399b2fb03..7c1726406 100644 --- a/data_descriptors/standard_name/convection_time_fraction.json +++ b/data_descriptors/standard_name/convection_time_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convection_time_fraction", + "id": "convection_time_fraction", "type": "standard_name", "name": "convection_time_fraction", "description": "\"Time fraction\" means a fraction of a time interval. The interval in question must be specified by the values or bounds of the time coordinate variable associated with the data. \"X_time_fraction\" means the fraction of the time interval during which X occurs.", diff --git a/data_descriptors/standard_name/convective_cloud_area_fraction.json b/data_descriptors/standard_name/convective_cloud_area_fraction.json index 0ab3ac544..903918bbc 100644 --- a/data_descriptors/standard_name/convective_cloud_area_fraction.json +++ b/data_descriptors/standard_name/convective_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_area_fraction", + "id": "convective_cloud_area_fraction", "type": "standard_name", "name": "convective_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names also exist for high, medium and low cloud types. Convective cloud is that produced by the convection schemes in an atmosphere model. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/convective_cloud_area_fraction_in_atmosphere_layer.json b/data_descriptors/standard_name/convective_cloud_area_fraction_in_atmosphere_layer.json index 1d9d06d2f..be8f3c7c1 100644 --- a/data_descriptors/standard_name/convective_cloud_area_fraction_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/convective_cloud_area_fraction_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_area_fraction_in_atmosphere_layer", + "id": "convective_cloud_area_fraction_in_atmosphere_layer", "type": "standard_name", "name": "convective_cloud_area_fraction_in_atmosphere_layer", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Standard names also exist for high, medium and low cloud types. Convective cloud is that produced by the convection schemes in an atmosphere model. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/convective_cloud_base_altitude.json b/data_descriptors/standard_name/convective_cloud_base_altitude.json index 19dab3c90..03af3263d 100644 --- a/data_descriptors/standard_name/convective_cloud_base_altitude.json +++ b/data_descriptors/standard_name/convective_cloud_base_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_base_altitude", + "id": "convective_cloud_base_altitude", "type": "standard_name", "name": "convective_cloud_base_altitude", "description": "cloud_base refers to the base of the lowest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/convective_cloud_base_height.json b/data_descriptors/standard_name/convective_cloud_base_height.json index 158c7bdc9..362adb358 100644 --- a/data_descriptors/standard_name/convective_cloud_base_height.json +++ b/data_descriptors/standard_name/convective_cloud_base_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_base_height", + "id": "convective_cloud_base_height", "type": "standard_name", "name": "convective_cloud_base_height", "description": "cloud_base refers to the base of the lowest cloud. Height is the vertical distance above the surface. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/convective_cloud_longwave_emissivity.json b/data_descriptors/standard_name/convective_cloud_longwave_emissivity.json index 6b1911a8e..83aef68df 100644 --- a/data_descriptors/standard_name/convective_cloud_longwave_emissivity.json +++ b/data_descriptors/standard_name/convective_cloud_longwave_emissivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_longwave_emissivity", + "id": "convective_cloud_longwave_emissivity", "type": "standard_name", "name": "convective_cloud_longwave_emissivity", "description": "Emissivity is the ratio of the power emitted by an object to the power that would be emitted by a perfect black body having the same temperature as the object. The emissivity is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength or radiation_frequency is included to specify either the wavelength or frequency. Convective cloud is that produced by the convection schemes in an atmosphere model. \"longwave\" means longwave radiation.", diff --git a/data_descriptors/standard_name/convective_cloud_top_altitude.json b/data_descriptors/standard_name/convective_cloud_top_altitude.json index a48903751..012580503 100644 --- a/data_descriptors/standard_name/convective_cloud_top_altitude.json +++ b/data_descriptors/standard_name/convective_cloud_top_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_top_altitude", + "id": "convective_cloud_top_altitude", "type": "standard_name", "name": "convective_cloud_top_altitude", "description": "cloud_top refers to the top of the highest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/convective_cloud_top_height.json b/data_descriptors/standard_name/convective_cloud_top_height.json index 950868c3c..ec50449e2 100644 --- a/data_descriptors/standard_name/convective_cloud_top_height.json +++ b/data_descriptors/standard_name/convective_cloud_top_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_cloud_top_height", + "id": "convective_cloud_top_height", "type": "standard_name", "name": "convective_cloud_top_height", "description": "cloud_top refers to the top of the highest cloud. Height is the vertical distance above the surface. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/convective_precipitation_amount.json b/data_descriptors/standard_name/convective_precipitation_amount.json index bb4a12963..c94acaf68 100644 --- a/data_descriptors/standard_name/convective_precipitation_amount.json +++ b/data_descriptors/standard_name/convective_precipitation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_precipitation_amount", + "id": "convective_precipitation_amount", "type": "standard_name", "name": "convective_precipitation_amount", "description": "\"Amount\" means mass per unit area. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. Convective precipitation is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/convective_precipitation_flux.json b/data_descriptors/standard_name/convective_precipitation_flux.json index e4dc47e27..14a8b728f 100644 --- a/data_descriptors/standard_name/convective_precipitation_flux.json +++ b/data_descriptors/standard_name/convective_precipitation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_precipitation_flux", + "id": "convective_precipitation_flux", "type": "standard_name", "name": "convective_precipitation_flux", "description": "Convective precipitation is that produced by the convection schemes in an atmosphere model. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/convective_precipitation_rate.json b/data_descriptors/standard_name/convective_precipitation_rate.json index 56e256208..20bd29cf3 100644 --- a/data_descriptors/standard_name/convective_precipitation_rate.json +++ b/data_descriptors/standard_name/convective_precipitation_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_precipitation_rate", + "id": "convective_precipitation_rate", "type": "standard_name", "name": "convective_precipitation_rate", "description": "\"Precipitation rate\" means the depth or thickness of the layer formed by precipitation per unit time. Convective precipitation is that produced by the convection schemes in an atmosphere model. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases.", diff --git a/data_descriptors/standard_name/convective_rainfall_amount.json b/data_descriptors/standard_name/convective_rainfall_amount.json index d80ac38c8..4de31af85 100644 --- a/data_descriptors/standard_name/convective_rainfall_amount.json +++ b/data_descriptors/standard_name/convective_rainfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_rainfall_amount", + "id": "convective_rainfall_amount", "type": "standard_name", "name": "convective_rainfall_amount", "description": "\"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/convective_rainfall_flux.json b/data_descriptors/standard_name/convective_rainfall_flux.json index 1bdd72a5c..e941756c7 100644 --- a/data_descriptors/standard_name/convective_rainfall_flux.json +++ b/data_descriptors/standard_name/convective_rainfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_rainfall_flux", + "id": "convective_rainfall_flux", "type": "standard_name", "name": "convective_rainfall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/convective_rainfall_rate.json b/data_descriptors/standard_name/convective_rainfall_rate.json index 2abd8d218..e0185414c 100644 --- a/data_descriptors/standard_name/convective_rainfall_rate.json +++ b/data_descriptors/standard_name/convective_rainfall_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_rainfall_rate", + "id": "convective_rainfall_rate", "type": "standard_name", "name": "convective_rainfall_rate", "description": null, diff --git a/data_descriptors/standard_name/convective_snowfall_amount.json b/data_descriptors/standard_name/convective_snowfall_amount.json index e7722728b..ccd638459 100644 --- a/data_descriptors/standard_name/convective_snowfall_amount.json +++ b/data_descriptors/standard_name/convective_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_snowfall_amount", + "id": "convective_snowfall_amount", "type": "standard_name", "name": "convective_snowfall_amount", "description": "\"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/convective_snowfall_flux.json b/data_descriptors/standard_name/convective_snowfall_flux.json index daad0fa25..1e04132ce 100644 --- a/data_descriptors/standard_name/convective_snowfall_flux.json +++ b/data_descriptors/standard_name/convective_snowfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/convective_snowfall_flux", + "id": "convective_snowfall_flux", "type": "standard_name", "name": "convective_snowfall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/coriolis_parameter.json b/data_descriptors/standard_name/coriolis_parameter.json index 01d2b3329..ff78f1507 100644 --- a/data_descriptors/standard_name/coriolis_parameter.json +++ b/data_descriptors/standard_name/coriolis_parameter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/coriolis_parameter", + "id": "coriolis_parameter", "type": "standard_name", "name": "coriolis_parameter", "description": "The Coriolis parameter is twice the component of the earth's angular velocity about the local vertical i.e. 2 W sin L, where L is latitude and W the angular speed of the earth.", diff --git a/data_descriptors/standard_name/correction_for_model_negative_specific_humidity.json b/data_descriptors/standard_name/correction_for_model_negative_specific_humidity.json index fb4c369f0..690aea3b8 100644 --- a/data_descriptors/standard_name/correction_for_model_negative_specific_humidity.json +++ b/data_descriptors/standard_name/correction_for_model_negative_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/correction_for_model_negative_specific_humidity", + "id": "correction_for_model_negative_specific_humidity", "type": "standard_name", "name": "correction_for_model_negative_specific_humidity", "description": "A numerical correction which is added to modelled negative specific humidities in order to obtain a value of zero.", diff --git a/data_descriptors/standard_name/covariance_over_longitude_of_northward_wind_and_air_temperature.json b/data_descriptors/standard_name/covariance_over_longitude_of_northward_wind_and_air_temperature.json index e4ccb04d2..409b4b721 100644 --- a/data_descriptors/standard_name/covariance_over_longitude_of_northward_wind_and_air_temperature.json +++ b/data_descriptors/standard_name/covariance_over_longitude_of_northward_wind_and_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/covariance_over_longitude_of_northward_wind_and_air_temperature", + "id": "covariance_over_longitude_of_northward_wind_and_air_temperature", "type": "standard_name", "name": "covariance_over_longitude_of_northward_wind_and_air_temperature", "description": "Covariance refers to the sample covariance rather than the population covariance. The quantity with standard name covariance_over_longitude_of_northward_wind_and_air_temperature is the covariance of the deviations of meridional air velocity and air temperature about their respective zonal mean values. The data variable must be accompanied by a vertical coordinate variable or scalar coordinate variable and is calculated on an isosurface of that vertical coordinate. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/density_ratio_of_dry_soil_to_water.json b/data_descriptors/standard_name/density_ratio_of_dry_soil_to_water.json index 16a29016e..b33c936a5 100644 --- a/data_descriptors/standard_name/density_ratio_of_dry_soil_to_water.json +++ b/data_descriptors/standard_name/density_ratio_of_dry_soil_to_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/density_ratio_of_dry_soil_to_water", + "id": "density_ratio_of_dry_soil_to_water", "type": "standard_name", "name": "density_ratio_of_dry_soil_to_water", "description": "The phrase \"ratio_of_X_to_Y\" means X/Y. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Also known as specific gravity, where soil represents a dry soil sample. The density of a substance is its mass per unit volume.", diff --git a/data_descriptors/standard_name/deployment_latitude.json b/data_descriptors/standard_name/deployment_latitude.json index 2ac01cb5f..bdba91567 100644 --- a/data_descriptors/standard_name/deployment_latitude.json +++ b/data_descriptors/standard_name/deployment_latitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/deployment_latitude", + "id": "deployment_latitude", "type": "standard_name", "name": "deployment_latitude", "description": "The latitude of deployment of a station or instrument. The term can be used whenever the deployment position of a station or instrument needs to be supplied along with other types of positions. If a data variable has only one latitude coordinate variable, the standard name of latitude should generally be preferred to deployment_latitude, because latitude is recognised by generic software. If the deployment latitude is also the nominal latitude for a discrete geometry (as in Section 9.5 of the CF convention), the deployment latitude should also, or instead, be recorded in a coordinate variable with the standard name of latitude and axis=\"Y\". Latitude is positive northward; its units of \"degree_north\" (or equivalent) indicate this explicitly.", diff --git a/data_descriptors/standard_name/deployment_longitude.json b/data_descriptors/standard_name/deployment_longitude.json index 20774c563..854a3ea2d 100644 --- a/data_descriptors/standard_name/deployment_longitude.json +++ b/data_descriptors/standard_name/deployment_longitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/deployment_longitude", + "id": "deployment_longitude", "type": "standard_name", "name": "deployment_longitude", "description": "The longitude of deployment of a station or instrument. The term can be used whenever the deployment position of a station or instrument needs to be supplied along with other types of positions. If a data variable has only one longitude coordinate variable, the standard name of longitude should generally be preferred to deployment_longitude, because longitude is recognised by generic software. If the deployment longitude is also the nominal longitude for a discrete geometry (as in Section 9.5 of the CF convention), the deployment longitude should also, or instead, be recorded in a coordinate variable with the standard name of longitude and axis=\"X\". Longitude is positive eastward; its units of \"degree_east\" (or equivalent) indicate this explicitly.", diff --git a/data_descriptors/standard_name/depth.json b/data_descriptors/standard_name/depth.json index 54f8d9253..98129dad1 100644 --- a/data_descriptors/standard_name/depth.json +++ b/data_descriptors/standard_name/depth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth", + "id": "depth", "type": "standard_name", "name": "depth", "description": "Depth is the vertical distance below the surface.", diff --git a/data_descriptors/standard_name/depth_at_base_of_unfrozen_ground.json b/data_descriptors/standard_name/depth_at_base_of_unfrozen_ground.json index 46252748e..f50edc1c5 100644 --- a/data_descriptors/standard_name/depth_at_base_of_unfrozen_ground.json +++ b/data_descriptors/standard_name/depth_at_base_of_unfrozen_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_at_base_of_unfrozen_ground", + "id": "depth_at_base_of_unfrozen_ground", "type": "standard_name", "name": "depth_at_base_of_unfrozen_ground", "description": "The phrase depth_at_base_of_unfrozen_ground is the instantaneous depth of the downward penetration of thaw from the ground surface at a given time. Permafrost is soil or rock that has remained at a temperature at or below zero degrees Celsius throughout the seasonal cycle for two or more consecutive years. The maximum measurable depth_at_base_of_unfrozen_ground value as recorded at the end of a thawing season corresponds to the permafrost_active_layer_thickness.", diff --git a/data_descriptors/standard_name/depth_at_maximum_upward_derivative_of_sea_water_potential_temperature.json b/data_descriptors/standard_name/depth_at_maximum_upward_derivative_of_sea_water_potential_temperature.json index 706396b08..b498b6498 100644 --- a/data_descriptors/standard_name/depth_at_maximum_upward_derivative_of_sea_water_potential_temperature.json +++ b/data_descriptors/standard_name/depth_at_maximum_upward_derivative_of_sea_water_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_at_maximum_upward_derivative_of_sea_water_potential_temperature", + "id": "depth_at_maximum_upward_derivative_of_sea_water_potential_temperature", "type": "standard_name", "name": "depth_at_maximum_upward_derivative_of_sea_water_potential_temperature", "description": "This quantity, often used to indicate the \"thermocline depth\", is the depth of the maximum vertical gradient of sea water potential temperature. Depth is the vertical distance below the surface. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", diff --git a/data_descriptors/standard_name/depth_at_shallowest_isotherm_defined_by_soil_temperature.json b/data_descriptors/standard_name/depth_at_shallowest_isotherm_defined_by_soil_temperature.json index d01af4dd2..937a8aa94 100644 --- a/data_descriptors/standard_name/depth_at_shallowest_isotherm_defined_by_soil_temperature.json +++ b/data_descriptors/standard_name/depth_at_shallowest_isotherm_defined_by_soil_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_at_shallowest_isotherm_defined_by_soil_temperature", + "id": "depth_at_shallowest_isotherm_defined_by_soil_temperature", "type": "standard_name", "name": "depth_at_shallowest_isotherm_defined_by_soil_temperature", "description": "Depth is the vertical distance below the surface. A soil temperature profile may go through one or more local minima or maxima. The \"depth at shallowest isotherm\" is the depth of the occurrence closest to the soil surface of an isotherm of the temperature specified by a coordinate variable or scalar coordinate variable with standard name soil_temperature.", diff --git a/data_descriptors/standard_name/depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json b/data_descriptors/standard_name/depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json index 12e5b6515..0806804a6 100644 --- a/data_descriptors/standard_name/depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", + "id": "depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "type": "standard_name", "name": "depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "description": "Depth is the vertical distance below the surface. 'Mole concentration' means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The concentration of any chemical species, whether particulate or dissolved, may vary with depth in the ocean. A depth profile may go through one or more local minima in concentration. The depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water is the depth of the local minimum in the oxygen concentration that occurs closest to the sea surface.", diff --git a/data_descriptors/standard_name/depth_below_geoid.json b/data_descriptors/standard_name/depth_below_geoid.json index f139daab2..b17ee6d71 100644 --- a/data_descriptors/standard_name/depth_below_geoid.json +++ b/data_descriptors/standard_name/depth_below_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_below_geoid", + "id": "depth_below_geoid", "type": "standard_name", "name": "depth_below_geoid", "description": "The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention. \"Depth_below_X\" means the vertical distance below the named surface X.", diff --git a/data_descriptors/standard_name/depth_below_sea_floor.json b/data_descriptors/standard_name/depth_below_sea_floor.json index ce7d16b8e..50ef8cfbf 100644 --- a/data_descriptors/standard_name/depth_below_sea_floor.json +++ b/data_descriptors/standard_name/depth_below_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_below_sea_floor", + "id": "depth_below_sea_floor", "type": "standard_name", "name": "depth_below_sea_floor", "description": "\"Depth_below_X\" means the vertical distance below the named surface X.", diff --git a/data_descriptors/standard_name/depth_of_isosurface_of_sea_water_potential_temperature.json b/data_descriptors/standard_name/depth_of_isosurface_of_sea_water_potential_temperature.json index 3c06cc4b9..51e4257b9 100644 --- a/data_descriptors/standard_name/depth_of_isosurface_of_sea_water_potential_temperature.json +++ b/data_descriptors/standard_name/depth_of_isosurface_of_sea_water_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/depth_of_isosurface_of_sea_water_potential_temperature", + "id": "depth_of_isosurface_of_sea_water_potential_temperature", "type": "standard_name", "name": "depth_of_isosurface_of_sea_water_potential_temperature", "description": "This quantity, sometimes called the \"isotherm depth\", is the depth (if it exists) at which the sea water potential temperature equals some specified value. This value should be specified in a scalar coordinate variable. Depth is the vertical distance below the surface. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", diff --git a/data_descriptors/standard_name/dew_point_depression.json b/data_descriptors/standard_name/dew_point_depression.json index 40061e883..f736b3c3a 100644 --- a/data_descriptors/standard_name/dew_point_depression.json +++ b/data_descriptors/standard_name/dew_point_depression.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dew_point_depression", + "id": "dew_point_depression", "type": "standard_name", "name": "dew_point_depression", "description": "Dew point depression is also called dew point deficit. It is the amount by which the air temperature exceeds its dew point temperature. Dew point temperature is the temperature at which a parcel of air reaches saturation upon being cooled at constant pressure and specific humidity. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/dew_point_temperature.json b/data_descriptors/standard_name/dew_point_temperature.json index cff0b32be..e6341055a 100644 --- a/data_descriptors/standard_name/dew_point_temperature.json +++ b/data_descriptors/standard_name/dew_point_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dew_point_temperature", + "id": "dew_point_temperature", "type": "standard_name", "name": "dew_point_temperature", "description": "Dew point temperature is the temperature at which a parcel of air reaches saturation upon being cooled at constant pressure and specific humidity. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/diameter_of_ambient_aerosol_particles.json b/data_descriptors/standard_name/diameter_of_ambient_aerosol_particles.json index 7d017ca8c..b6477c6dd 100644 --- a/data_descriptors/standard_name/diameter_of_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/diameter_of_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/diameter_of_ambient_aerosol_particles", + "id": "diameter_of_ambient_aerosol_particles", "type": "standard_name", "name": "diameter_of_ambient_aerosol_particles", "description": "\"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature.json b/data_descriptors/standard_name/difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature.json index 6bb8afbfb..d1a09f32d 100644 --- a/data_descriptors/standard_name/difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature.json +++ b/data_descriptors/standard_name/difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature", + "id": "difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature", "type": "standard_name", "name": "difference_between_sea_surface_skin_temperature_and_sea_surface_subskin_temperature", "description": "This variable quantifies the temperature difference between the skin temperature (sea_surface_skin_temperature) and the subskin temperature (sea_surface_subskin_temperature) due to the turbulent and radiative heat fluxes at the air-sea interface. This difference is commonly referred to as the \u201ccool skin effect\u201d as the solar radiation absorbed within the very thin thermal subskin layer is typically negligible compared to ocean surface heat loss from the combined sensible, latent, and net longwave radiation heat fluxes.", diff --git a/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature.json b/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature.json index 9af395fe3..655e838b8 100644 --- a/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature.json +++ b/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature", + "id": "difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature", "type": "standard_name", "name": "difference_between_sea_surface_subskin_temperature_and_sea_surface_foundation_temperature", "description": "This variable quantifies the temperature difference between the top (sea_surface_subskin_temperature) and bottom (sea_surface_foundation_temperature) of the diurnal warm layer. This diurnal warm layer, caused by absorption of solar radiation in the absence of strong mixing, together with a cool skin effect, account for the total temperature difference between the sea_surface_skin_temperature and the sea_surface_foundation_temperature. The cool skin effect is associated with the turbulent and infrared radiative heat loss at the air-sea interface. Freshwater fluxes may also affect this variable (sea_surface_subskin_temperature_minus_sea_surface_foundation_temperature).", diff --git a/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature.json b/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature.json index 3fa2b5c52..9799199be 100644 --- a/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature.json +++ b/data_descriptors/standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature", + "id": "difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature", "type": "standard_name", "name": "difference_between_sea_surface_subskin_temperature_and_sea_surface_temperature", "description": "This variable quantifies the temperature difference between the top of the diurnal warm layer (sea_surface_subskin_temperature) and the in-situ measured sea surface temperature at depth (sea_surface_temperature). A diurnal warm layer can develop in the top few meters of the ocean through the absorption of solar radiation, if surface mixing is sufficiently weak.", diff --git a/data_descriptors/standard_name/difference_between_sea_surface_temperature_and_air_temperature.json b/data_descriptors/standard_name/difference_between_sea_surface_temperature_and_air_temperature.json index 66433d6e1..ced859023 100644 --- a/data_descriptors/standard_name/difference_between_sea_surface_temperature_and_air_temperature.json +++ b/data_descriptors/standard_name/difference_between_sea_surface_temperature_and_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/difference_between_sea_surface_temperature_and_air_temperature", + "id": "difference_between_sea_surface_temperature_and_air_temperature", "type": "standard_name", "name": "difference_between_sea_surface_temperature_and_air_temperature", "description": "Sea surface temperature is usually abbreviated as \"SST\". It is the temperature of sea water near the surface (including the part under sea-ice, if any), not the skin or interface temperature, whose standard names are sea_surface_skin_temperature and surface_temperature, respectively. For the temperature of sea water at a particular depth or layer, a data variable of \"sea_water_temperature\" with a vertical coordinate axis should be used. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/difference_of_air_pressure_from_model_reference.json b/data_descriptors/standard_name/difference_of_air_pressure_from_model_reference.json index 719c04d3b..c90521f59 100644 --- a/data_descriptors/standard_name/difference_of_air_pressure_from_model_reference.json +++ b/data_descriptors/standard_name/difference_of_air_pressure_from_model_reference.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/difference_of_air_pressure_from_model_reference", + "id": "difference_of_air_pressure_from_model_reference", "type": "standard_name", "name": "difference_of_air_pressure_from_model_reference", "description": "In some atmosphere models, the difference of air pressure from model reference is a prognostic variable, instead of the air pressure itself. The model reference air pressure is a model-dependent constant. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air.json index 3af6fcb46..4ccef0229 100644 --- a/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/diffuse_downwelling_shortwave_flux_in_air", + "id": "diffuse_downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "diffuse_downwelling_shortwave_flux_in_air", "description": "\"Diffuse\" radiation is radiation that has been scattered by gas molecules in the atmosphere and by particles such as cloud droplets and aerosols. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json index 67b71213b..3a28a0a71 100644 --- a/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", + "id": "diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", "description": "\"Diffuse\" radiation is radiation that has been scattered by gas molecules in the atmosphere and by particles such as cloud droplets and aerosols. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/dimensionless_exner_function.json b/data_descriptors/standard_name/dimensionless_exner_function.json index de30b6719..3a29d434f 100644 --- a/data_descriptors/standard_name/dimensionless_exner_function.json +++ b/data_descriptors/standard_name/dimensionless_exner_function.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dimensionless_exner_function", + "id": "dimensionless_exner_function", "type": "standard_name", "name": "dimensionless_exner_function", "description": "The term \"Exner function\" is applied to various quantities in the literature. \"Dimensionless Exner function\" is the standard name of (p/p0)^(R/Cp), where p is pressure, p0 a reference pressure, R the gas constant and Cp the specific heat at constant pressure. This quantity is also the ratio of in-situ to potential temperature. Standard names for other variants can be defined on request. To specify the reference pressure to which the quantity applies, provide a scalar coordinate variable with standard name reference_pressure.", diff --git a/data_descriptors/standard_name/direct_downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/direct_downwelling_shortwave_flux_in_air.json index 5c4d48d56..d122986c1 100644 --- a/data_descriptors/standard_name/direct_downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/direct_downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/direct_downwelling_shortwave_flux_in_air", + "id": "direct_downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "direct_downwelling_shortwave_flux_in_air", "description": "\"Direct\" (also known as \"beam\") radiation is radiation that has followed a direct path from the sun and is alternatively known as \"direct insolation\". Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/direction_of_radial_vector_away_from_instrument.json b/data_descriptors/standard_name/direction_of_radial_vector_away_from_instrument.json index 5121a4894..ef54cdd9f 100644 --- a/data_descriptors/standard_name/direction_of_radial_vector_away_from_instrument.json +++ b/data_descriptors/standard_name/direction_of_radial_vector_away_from_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/direction_of_radial_vector_away_from_instrument", + "id": "direction_of_radial_vector_away_from_instrument", "type": "standard_name", "name": "direction_of_radial_vector_away_from_instrument", "description": "The phrase \"direction_of_X\" means direction of a vector, a bearing. The direction is measured positive clockwise from due north. The direction_of_radial_vector_away_from_instrument is the direction in which the instrument itself is pointing. The \"instrument\" (examples are radar and lidar) is the device used to make an observation. The standard name direction_of_radial_vector_toward_instrument should be used for a data variable having the opposite sign convention.", diff --git a/data_descriptors/standard_name/direction_of_radial_vector_toward_instrument.json b/data_descriptors/standard_name/direction_of_radial_vector_toward_instrument.json index 1c91c7af5..69f1d09ee 100644 --- a/data_descriptors/standard_name/direction_of_radial_vector_toward_instrument.json +++ b/data_descriptors/standard_name/direction_of_radial_vector_toward_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/direction_of_radial_vector_toward_instrument", + "id": "direction_of_radial_vector_toward_instrument", "type": "standard_name", "name": "direction_of_radial_vector_toward_instrument", "description": "The phrase \"direction_of_X\" means direction of a vector, a bearing. The direction is measured positive clockwise from due north. The direction_of_radial_vector_toward_instrument is the direction opposite to that in which the instrument itself is pointing. The \"instrument\" (examples are radar and lidar) is the device used to make an observation. The standard name direction_of_radial_vector_away_from_instrument should be used for a data variable having the opposite sign convention.", diff --git a/data_descriptors/standard_name/direction_of_sea_ice_displacement.json b/data_descriptors/standard_name/direction_of_sea_ice_displacement.json index ddb7547cb..6a28c18d8 100644 --- a/data_descriptors/standard_name/direction_of_sea_ice_displacement.json +++ b/data_descriptors/standard_name/direction_of_sea_ice_displacement.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/direction_of_sea_ice_displacement", + "id": "direction_of_sea_ice_displacement", "type": "standard_name", "name": "direction_of_sea_ice_displacement", "description": "The phrase \"direction_of_X\" means direction of a vector, a bearing. \"Displacement\" means the change in geospatial position of an object that has moved over time. If possible, the time interval over which the motion took place should be specified using a bounds variable for the time coordinate variable. A displacement can be represented as a vector. Such a vector should however not be interpreted as describing a rectilinear, constant speed motion but merely as an indication that the start point of the vector is found at the tip of the vector after the time interval associated with the displacement variable. A displacement does not prescribe a trajectory. Sea ice displacement can be defined as a two-dimensional vector, with no vertical component. In that case, \"displacement\" is also the distance across the earth's surface calculated from the change in a moving object's geospatial position between the start and end of the time interval associated with the displacement variable. The \"direction of displacement\" is the angle between due north and the displacement vector. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/direction_of_sea_ice_velocity.json b/data_descriptors/standard_name/direction_of_sea_ice_velocity.json index 4d86be13a..7ee8565dc 100644 --- a/data_descriptors/standard_name/direction_of_sea_ice_velocity.json +++ b/data_descriptors/standard_name/direction_of_sea_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/direction_of_sea_ice_velocity", + "id": "direction_of_sea_ice_velocity", "type": "standard_name", "name": "direction_of_sea_ice_velocity", "description": "The phrase \"direction_of_X\" means direction of a vector, a bearing. A velocity is a vector quantity. Sea ice velocity is defined as a two-dimensional vector, with no vertical component. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/distance_from_geocenter.json b/data_descriptors/standard_name/distance_from_geocenter.json index dda5e8c4f..f5f171dd0 100644 --- a/data_descriptors/standard_name/distance_from_geocenter.json +++ b/data_descriptors/standard_name/distance_from_geocenter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/distance_from_geocenter", + "id": "distance_from_geocenter", "type": "standard_name", "name": "distance_from_geocenter", "description": "A measure of distance from the Earth's geocenter, commonly used in satellite tracks.", diff --git a/data_descriptors/standard_name/distance_from_sun.json b/data_descriptors/standard_name/distance_from_sun.json index 5ebacb9fd..d949848c7 100644 --- a/data_descriptors/standard_name/distance_from_sun.json +++ b/data_descriptors/standard_name/distance_from_sun.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/distance_from_sun", + "id": "distance_from_sun", "type": "standard_name", "name": "distance_from_sun", "description": "The distance from the sun to the point of observation.", diff --git a/data_descriptors/standard_name/distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection.json b/data_descriptors/standard_name/distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection.json index 54371ebba..162efdf9d 100644 --- a/data_descriptors/standard_name/distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection.json +++ b/data_descriptors/standard_name/distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection", + "id": "distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection", "type": "standard_name", "name": "distance_from_tropical_cyclone_center_to_leading_edge_of_displaced_convection", "description": "The great circle distance measured from the tropical cyclone center to the leading edge of displaced convection, which is defined as the closest point that exceeds a threshold brightness temperature at top of atmosphere limit. The threshold applied should be recorded in a coordinate variable having the standard name of toa_brightness_temperature. A coordinate variable with standard name of radiation_wavelength, sensor_band_central_radiation_wavelength, or radiation_frequency may be specified to indicate that the brightness temperature applies at specific wavelengths or frequencies.", diff --git a/data_descriptors/standard_name/divergence_of_sea_ice_velocity.json b/data_descriptors/standard_name/divergence_of_sea_ice_velocity.json index 1243b2d42..502a50225 100644 --- a/data_descriptors/standard_name/divergence_of_sea_ice_velocity.json +++ b/data_descriptors/standard_name/divergence_of_sea_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/divergence_of_sea_ice_velocity", + "id": "divergence_of_sea_ice_velocity", "type": "standard_name", "name": "divergence_of_sea_ice_velocity", "description": "The phrase \"[horizontal_]divergence_of_X\" means [horizontal] divergence of a vector X; if X does not have a vertical component then \"horizontal\" should be omitted. A velocity is a vector quantity. Sea ice velocity is defined as a two-dimensional vector, with no vertical component. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/divergence_of_wind.json b/data_descriptors/standard_name/divergence_of_wind.json index 191e0df19..6997607a5 100644 --- a/data_descriptors/standard_name/divergence_of_wind.json +++ b/data_descriptors/standard_name/divergence_of_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/divergence_of_wind", + "id": "divergence_of_wind", "type": "standard_name", "name": "divergence_of_wind", "description": "\"[horizontal_]divergence_of_X\" means [horizontal] divergence of a vector X; if X does not have a vertical component then \"horizontal\" should be omitted. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/downward_air_velocity.json b/data_descriptors/standard_name/downward_air_velocity.json index ba98ba191..3bd58a3cc 100644 --- a/data_descriptors/standard_name/downward_air_velocity.json +++ b/data_descriptors/standard_name/downward_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_air_velocity", + "id": "downward_air_velocity", "type": "standard_name", "name": "downward_air_velocity", "description": "A velocity is a vector quantity.\"Downward\" indicates a vector component which is positive when directed downward (negative upward). Downward air velocity is the vertical component of the 3D air velocity vector. The standard name upward_air_velocity may be used for a vector component with the opposite sign convention.", diff --git a/data_descriptors/standard_name/downward_dry_static_energy_flux_due_to_diffusion.json b/data_descriptors/standard_name/downward_dry_static_energy_flux_due_to_diffusion.json index 5ecb0f07a..f81db5014 100644 --- a/data_descriptors/standard_name/downward_dry_static_energy_flux_due_to_diffusion.json +++ b/data_descriptors/standard_name/downward_dry_static_energy_flux_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_dry_static_energy_flux_due_to_diffusion", + "id": "downward_dry_static_energy_flux_due_to_diffusion", "type": "standard_name", "name": "downward_dry_static_energy_flux_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air.json b/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air.json index 2a663d045..02bfd06f1 100644 --- a/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air.json +++ b/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_eastward_momentum_flux_in_air", + "id": "downward_eastward_momentum_flux_in_air", "type": "standard_name", "name": "downward_eastward_momentum_flux_in_air", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Downward eastward\" indicates the ZX component of a tensor. Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air_due_to_diffusion.json b/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air_due_to_diffusion.json index 6dc20765e..01a3ef377 100644 --- a/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air_due_to_diffusion.json +++ b/data_descriptors/standard_name/downward_eastward_momentum_flux_in_air_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_eastward_momentum_flux_in_air_due_to_diffusion", + "id": "downward_eastward_momentum_flux_in_air_due_to_diffusion", "type": "standard_name", "name": "downward_eastward_momentum_flux_in_air_due_to_diffusion", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Downward eastward\" indicates the ZX component of a tensor. Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/downward_eastward_stress_at_sea_ice_base.json b/data_descriptors/standard_name/downward_eastward_stress_at_sea_ice_base.json index 16a0a5136..d871c78ea 100644 --- a/data_descriptors/standard_name/downward_eastward_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/downward_eastward_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_eastward_stress_at_sea_ice_base", + "id": "downward_eastward_stress_at_sea_ice_base", "type": "standard_name", "name": "downward_eastward_stress_at_sea_ice_base", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_snow.json b/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_snow.json index 8b3ce5105..5fe2b6d66 100644 --- a/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_snow.json +++ b/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_heat_flux_at_ground_level_in_snow", + "id": "downward_heat_flux_at_ground_level_in_snow", "type": "standard_name", "name": "downward_heat_flux_at_ground_level_in_snow", "description": "ground_level means the land surface (beneath the snow and surface water, if any). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_soil.json b/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_soil.json index dfc5610fe..8715cfeb6 100644 --- a/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_soil.json +++ b/data_descriptors/standard_name/downward_heat_flux_at_ground_level_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_heat_flux_at_ground_level_in_soil", + "id": "downward_heat_flux_at_ground_level_in_soil", "type": "standard_name", "name": "downward_heat_flux_at_ground_level_in_soil", "description": "ground_level means the land surface (beneath the snow and surface water, if any). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_heat_flux_in_air.json b/data_descriptors/standard_name/downward_heat_flux_in_air.json index 50f37ed3b..dbabf6c73 100644 --- a/data_descriptors/standard_name/downward_heat_flux_in_air.json +++ b/data_descriptors/standard_name/downward_heat_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_heat_flux_in_air", + "id": "downward_heat_flux_in_air", "type": "standard_name", "name": "downward_heat_flux_in_air", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). The vertical heat flux in air is the sum of all heat fluxes i.e. radiative, latent and sensible. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_heat_flux_in_floating_ice.json b/data_descriptors/standard_name/downward_heat_flux_in_floating_ice.json index 681502c42..16121d1c2 100644 --- a/data_descriptors/standard_name/downward_heat_flux_in_floating_ice.json +++ b/data_descriptors/standard_name/downward_heat_flux_in_floating_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_heat_flux_in_floating_ice", + "id": "downward_heat_flux_in_floating_ice", "type": "standard_name", "name": "downward_heat_flux_in_floating_ice", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Floating ice\" means any ice that is floating on water, e.g. on a sea or lake surface.", diff --git a/data_descriptors/standard_name/downward_heat_flux_in_sea_ice.json b/data_descriptors/standard_name/downward_heat_flux_in_sea_ice.json index 7b04ed036..6737c838e 100644 --- a/data_descriptors/standard_name/downward_heat_flux_in_sea_ice.json +++ b/data_descriptors/standard_name/downward_heat_flux_in_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_heat_flux_in_sea_ice", + "id": "downward_heat_flux_in_sea_ice", "type": "standard_name", "name": "downward_heat_flux_in_sea_ice", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downward_heat_flux_in_soil.json b/data_descriptors/standard_name/downward_heat_flux_in_soil.json index 33d8f9857..0e455adbe 100644 --- a/data_descriptors/standard_name/downward_heat_flux_in_soil.json +++ b/data_descriptors/standard_name/downward_heat_flux_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_heat_flux_in_soil", + "id": "downward_heat_flux_in_soil", "type": "standard_name", "name": "downward_heat_flux_in_soil", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_liquid_water_mass_flux_into_groundwater.json b/data_descriptors/standard_name/downward_liquid_water_mass_flux_into_groundwater.json index 54045087a..903623ba6 100644 --- a/data_descriptors/standard_name/downward_liquid_water_mass_flux_into_groundwater.json +++ b/data_descriptors/standard_name/downward_liquid_water_mass_flux_into_groundwater.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_liquid_water_mass_flux_into_groundwater", + "id": "downward_liquid_water_mass_flux_into_groundwater", "type": "standard_name", "name": "downward_liquid_water_mass_flux_into_groundwater", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Groundwater is subsurface water below the depth of the water table. The quantity with standard name liquid_water_mass_flux_from_soil_to_groundwater is the downward flux of liquid water within soil at the depth of the water table, or downward flux from the base of the soil model if the water table depth is greater.", diff --git a/data_descriptors/standard_name/downward_northward_momentum_flux_in_air.json b/data_descriptors/standard_name/downward_northward_momentum_flux_in_air.json index 6b401132c..5f059af7c 100644 --- a/data_descriptors/standard_name/downward_northward_momentum_flux_in_air.json +++ b/data_descriptors/standard_name/downward_northward_momentum_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_northward_momentum_flux_in_air", + "id": "downward_northward_momentum_flux_in_air", "type": "standard_name", "name": "downward_northward_momentum_flux_in_air", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Downward northward\" indicates the ZY component of a tensor. Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_northward_momentum_flux_in_air_due_to_diffusion.json b/data_descriptors/standard_name/downward_northward_momentum_flux_in_air_due_to_diffusion.json index 15ac3c7dd..60bebb924 100644 --- a/data_descriptors/standard_name/downward_northward_momentum_flux_in_air_due_to_diffusion.json +++ b/data_descriptors/standard_name/downward_northward_momentum_flux_in_air_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_northward_momentum_flux_in_air_due_to_diffusion", + "id": "downward_northward_momentum_flux_in_air_due_to_diffusion", "type": "standard_name", "name": "downward_northward_momentum_flux_in_air_due_to_diffusion", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Downward northward\" indicates the ZY component of a tensor. Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/downward_northward_stress_at_sea_ice_base.json b/data_descriptors/standard_name/downward_northward_stress_at_sea_ice_base.json index f321d16c1..54df9b54b 100644 --- a/data_descriptors/standard_name/downward_northward_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/downward_northward_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_northward_stress_at_sea_ice_base", + "id": "downward_northward_stress_at_sea_ice_base", "type": "standard_name", "name": "downward_northward_stress_at_sea_ice_base", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downward_sea_ice_basal_salt_flux.json b/data_descriptors/standard_name/downward_sea_ice_basal_salt_flux.json index 3795da37b..8416e4dfd 100644 --- a/data_descriptors/standard_name/downward_sea_ice_basal_salt_flux.json +++ b/data_descriptors/standard_name/downward_sea_ice_basal_salt_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_sea_ice_basal_salt_flux", + "id": "downward_sea_ice_basal_salt_flux", "type": "standard_name", "name": "downward_sea_ice_basal_salt_flux", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downward_water_vapor_flux_in_air_due_to_diffusion.json b/data_descriptors/standard_name/downward_water_vapor_flux_in_air_due_to_diffusion.json index 43ad8dbaa..906c25f5a 100644 --- a/data_descriptors/standard_name/downward_water_vapor_flux_in_air_due_to_diffusion.json +++ b/data_descriptors/standard_name/downward_water_vapor_flux_in_air_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_water_vapor_flux_in_air_due_to_diffusion", + "id": "downward_water_vapor_flux_in_air_due_to_diffusion", "type": "standard_name", "name": "downward_water_vapor_flux_in_air_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downward_x_stress_at_sea_ice_base.json b/data_descriptors/standard_name/downward_x_stress_at_sea_ice_base.json index 01f73a51c..0acfc81d0 100644 --- a/data_descriptors/standard_name/downward_x_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/downward_x_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_x_stress_at_sea_ice_base", + "id": "downward_x_stress_at_sea_ice_base", "type": "standard_name", "name": "downward_x_stress_at_sea_ice_base", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downward_x_stress_at_sea_water_surface.json b/data_descriptors/standard_name/downward_x_stress_at_sea_water_surface.json index 29dd37aeb..ba8f71490 100644 --- a/data_descriptors/standard_name/downward_x_stress_at_sea_water_surface.json +++ b/data_descriptors/standard_name/downward_x_stress_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_x_stress_at_sea_water_surface", + "id": "downward_x_stress_at_sea_water_surface", "type": "standard_name", "name": "downward_x_stress_at_sea_water_surface", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"x\" indicates a vector component along the grid x-axis, positive with increasing x. A downward x stress is a downward flux of momentum towards the positive direction of the model's x-axis. The phrase \"sea water surface\" means the upper boundary of the liquid portion of an ocean or sea, including the boundary to floating ice if present.", diff --git a/data_descriptors/standard_name/downward_x_stress_correction_at_sea_water_surface.json b/data_descriptors/standard_name/downward_x_stress_correction_at_sea_water_surface.json index 7a7c2c724..aa4c97c40 100644 --- a/data_descriptors/standard_name/downward_x_stress_correction_at_sea_water_surface.json +++ b/data_descriptors/standard_name/downward_x_stress_correction_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_x_stress_correction_at_sea_water_surface", + "id": "downward_x_stress_correction_at_sea_water_surface", "type": "standard_name", "name": "downward_x_stress_correction_at_sea_water_surface", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"x\" indicates a vector component along the grid x-axis, positive with increasing x. A downward x stress is a downward flux of momentum towards the positive direction of the model's x-axis. A positive correction is downward i.e. added to the ocean. The phrase \"sea water surface\" means the upper boundary of the liquid portion of an ocean or sea, including the boundary to floating ice if present.", diff --git a/data_descriptors/standard_name/downward_y_stress_at_sea_ice_base.json b/data_descriptors/standard_name/downward_y_stress_at_sea_ice_base.json index e09b13110..4bec76fbb 100644 --- a/data_descriptors/standard_name/downward_y_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/downward_y_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_y_stress_at_sea_ice_base", + "id": "downward_y_stress_at_sea_ice_base", "type": "standard_name", "name": "downward_y_stress_at_sea_ice_base", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downward_y_stress_at_sea_water_surface.json b/data_descriptors/standard_name/downward_y_stress_at_sea_water_surface.json index 9df58818a..02996a526 100644 --- a/data_descriptors/standard_name/downward_y_stress_at_sea_water_surface.json +++ b/data_descriptors/standard_name/downward_y_stress_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_y_stress_at_sea_water_surface", + "id": "downward_y_stress_at_sea_water_surface", "type": "standard_name", "name": "downward_y_stress_at_sea_water_surface", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"y\" indicates a vector component along the grid y-axis, positive with increasing y. A downward y stress is a downward flux of momentum towards the positive direction of the model's y-axis. The phrase \"sea water surface\" means the upper boundary of the liquid portion of an ocean or sea, including the boundary to floating ice if present.", diff --git a/data_descriptors/standard_name/downward_y_stress_correction_at_sea_water_surface.json b/data_descriptors/standard_name/downward_y_stress_correction_at_sea_water_surface.json index 0ee30335f..113999601 100644 --- a/data_descriptors/standard_name/downward_y_stress_correction_at_sea_water_surface.json +++ b/data_descriptors/standard_name/downward_y_stress_correction_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downward_y_stress_correction_at_sea_water_surface", + "id": "downward_y_stress_correction_at_sea_water_surface", "type": "standard_name", "name": "downward_y_stress_correction_at_sea_water_surface", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"y\" indicates a vector component along the grid y-axis, positive with increasing y. A downward y stress is a downward flux of momentum towards the positive direction of the model's y-axis. A positive correction is downward i.e. added to the ocean. The phrase \"sea water surface\" means the upper boundary of the liquid portion of an ocean or sea, including the boundary to floating ice if present.", diff --git a/data_descriptors/standard_name/downwelling_longwave_flux_in_air.json b/data_descriptors/standard_name/downwelling_longwave_flux_in_air.json index db2aad608..ee03643cc 100644 --- a/data_descriptors/standard_name/downwelling_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/downwelling_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_longwave_flux_in_air", + "id": "downwelling_longwave_flux_in_air", "type": "standard_name", "name": "downwelling_longwave_flux_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky.json index 92fd63ad0..556271eb3 100644 --- a/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky", + "id": "downwelling_longwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "downwelling_longwave_flux_in_air_assuming_clear_sky", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 489a6feed..9687c5caf 100644 --- a/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index b684a4092..fbcf284bd 100644 --- a/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/downwelling_longwave_radiance_in_air.json b/data_descriptors/standard_name/downwelling_longwave_radiance_in_air.json index d7aee935e..11930eba0 100644 --- a/data_descriptors/standard_name/downwelling_longwave_radiance_in_air.json +++ b/data_descriptors/standard_name/downwelling_longwave_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_longwave_radiance_in_air", + "id": "downwelling_longwave_radiance_in_air", "type": "standard_name", "name": "downwelling_longwave_radiance_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/downwelling_photon_flux_in_sea_water.json b/data_descriptors/standard_name/downwelling_photon_flux_in_sea_water.json index 4e8556481..697bb83ad 100644 --- a/data_descriptors/standard_name/downwelling_photon_flux_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photon_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photon_flux_in_sea_water", + "id": "downwelling_photon_flux_in_sea_water", "type": "standard_name", "name": "downwelling_photon_flux_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_photon_flux_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/downwelling_photon_flux_per_unit_wavelength_in_sea_water.json index dabe208b2..410a2e3c0 100644 --- a/data_descriptors/standard_name/downwelling_photon_flux_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photon_flux_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photon_flux_per_unit_wavelength_in_sea_water", + "id": "downwelling_photon_flux_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "downwelling_photon_flux_per_unit_wavelength_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/downwelling_photon_radiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_photon_radiance_in_sea_water.json index e654e1d97..9e53814b7 100644 --- a/data_descriptors/standard_name/downwelling_photon_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photon_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photon_radiance_in_sea_water", + "id": "downwelling_photon_radiance_in_sea_water", "type": "standard_name", "name": "downwelling_photon_radiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json index 0bea7ab45..295c73957 100644 --- a/data_descriptors/standard_name/downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photon_radiance_per_unit_wavelength_in_sea_water", + "id": "downwelling_photon_radiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "downwelling_photon_radiance_per_unit_wavelength_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_in_sea_water.json index 42eb8f809..5f11d20b3 100644 --- a/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photon_spherical_irradiance_in_sea_water", + "id": "downwelling_photon_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "downwelling_photon_spherical_irradiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or \"2-pi\") collector. Radiation incident on a 4-pi collector has a standard name referring to \"omnidirectional spherical irradiance\". A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json index 356e7dee5..faabe4f0a 100644 --- a/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water", + "id": "downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or \"2-pi\") collector. The direction (\"up/downwelling\") is specified. Radiation incident on a 4-pi collector has a standard name referring to \"omnidirectional spherical irradiance\". A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/downwelling_photosynthetic_photon_flux_in_sea_water.json b/data_descriptors/standard_name/downwelling_photosynthetic_photon_flux_in_sea_water.json index 442e6b9e9..ff44b6045 100644 --- a/data_descriptors/standard_name/downwelling_photosynthetic_photon_flux_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photosynthetic_photon_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photosynthetic_photon_flux_in_sea_water", + "id": "downwelling_photosynthetic_photon_flux_in_sea_water", "type": "standard_name", "name": "downwelling_photosynthetic_photon_flux_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_photosynthetic_photon_radiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_photosynthetic_photon_radiance_in_sea_water.json index 9031b5723..6b265a67d 100644 --- a/data_descriptors/standard_name/downwelling_photosynthetic_photon_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photosynthetic_photon_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photosynthetic_photon_radiance_in_sea_water", + "id": "downwelling_photosynthetic_photon_radiance_in_sea_water", "type": "standard_name", "name": "downwelling_photosynthetic_photon_radiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json index 98225ba6c..a5f242d73 100644 --- a/data_descriptors/standard_name/downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water", + "id": "downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or \"2-pi\") collector. The direction (\"up/downwelling\") is specified. Radiation incident on a 4-pi collector has a standard name referring to \"omnidirectional spherical irradiance\". A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/downwelling_photosynthetic_radiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_photosynthetic_radiance_in_sea_water.json index 76218e329..c9d8a984e 100644 --- a/data_descriptors/standard_name/downwelling_photosynthetic_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photosynthetic_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photosynthetic_radiance_in_sea_water", + "id": "downwelling_photosynthetic_radiance_in_sea_water", "type": "standard_name", "name": "downwelling_photosynthetic_radiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength.", diff --git a/data_descriptors/standard_name/downwelling_photosynthetic_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/downwelling_photosynthetic_radiative_flux_in_sea_water.json index b1d631977..802d66604 100644 --- a/data_descriptors/standard_name/downwelling_photosynthetic_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photosynthetic_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photosynthetic_radiative_flux_in_sea_water", + "id": "downwelling_photosynthetic_radiative_flux_in_sea_water", "type": "standard_name", "name": "downwelling_photosynthetic_radiative_flux_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_photosynthetic_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_photosynthetic_spherical_irradiance_in_sea_water.json index 8e52a75c4..491850d54 100644 --- a/data_descriptors/standard_name/downwelling_photosynthetic_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_photosynthetic_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_photosynthetic_spherical_irradiance_in_sea_water", + "id": "downwelling_photosynthetic_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "downwelling_photosynthetic_spherical_irradiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Spherical irradiance is the radiation incident on unit area of a hemispherical (or \"2-pi\") collector. It is sometimes called \"scalar irradiance\". The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\".", diff --git a/data_descriptors/standard_name/downwelling_radiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_radiance_in_sea_water.json index 86916b14b..996af12b5 100644 --- a/data_descriptors/standard_name/downwelling_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_radiance_in_sea_water", + "id": "downwelling_radiance_in_sea_water", "type": "standard_name", "name": "downwelling_radiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_air.json index d34ae1481..fd4180093 100644 --- a/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_radiance_per_unit_wavelength_in_air", + "id": "downwelling_radiance_per_unit_wavelength_in_air", "type": "standard_name", "name": "downwelling_radiance_per_unit_wavelength_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_sea_water.json index c8b97757b..f1214029d 100644 --- a/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_radiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_radiance_per_unit_wavelength_in_sea_water", + "id": "downwelling_radiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "downwelling_radiance_per_unit_wavelength_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/downwelling_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/downwelling_radiative_flux_in_sea_water.json index 493ab37e3..9bc109f4a 100644 --- a/data_descriptors/standard_name/downwelling_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_radiative_flux_in_sea_water", + "id": "downwelling_radiative_flux_in_sea_water", "type": "standard_name", "name": "downwelling_radiative_flux_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_air.json index 751069709..9a8314668 100644 --- a/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_radiative_flux_per_unit_wavelength_in_air", + "id": "downwelling_radiative_flux_per_unit_wavelength_in_air", "type": "standard_name", "name": "downwelling_radiative_flux_per_unit_wavelength_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json index ff8312774..03e6722dc 100644 --- a/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_radiative_flux_per_unit_wavelength_in_sea_water", + "id": "downwelling_radiative_flux_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "downwelling_radiative_flux_per_unit_wavelength_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air.json index ebbbbb6fd..d616a57a3 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_air", + "id": "downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "downwelling_shortwave_flux_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky.json index 9cb5ab420..2e98ad056 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky", + "id": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json index 8f3f0c5ee..b2e94dd9d 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", + "id": "downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "type": "standard_name", "name": "downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 9b06061c0..652e81b14 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index 0423bc82d..a712ee56c 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water.json index a9a816f81..ff6bf674c 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_sea_water", + "id": "downwelling_shortwave_flux_in_sea_water", "type": "standard_name", "name": "downwelling_shortwave_flux_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water_at_sea_ice_base.json b/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water_at_sea_ice_base.json index bd09eed44..9348f6672 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water_at_sea_ice_base.json +++ b/data_descriptors/standard_name/downwelling_shortwave_flux_in_sea_water_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_flux_in_sea_water_at_sea_ice_base", + "id": "downwelling_shortwave_flux_in_sea_water_at_sea_ice_base", "type": "standard_name", "name": "downwelling_shortwave_flux_in_sea_water_at_sea_ice_base", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/downwelling_shortwave_radiance_in_air.json b/data_descriptors/standard_name/downwelling_shortwave_radiance_in_air.json index f6818452e..1c186a736 100644 --- a/data_descriptors/standard_name/downwelling_shortwave_radiance_in_air.json +++ b/data_descriptors/standard_name/downwelling_shortwave_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_shortwave_radiance_in_air", + "id": "downwelling_shortwave_radiance_in_air", "type": "standard_name", "name": "downwelling_shortwave_radiance_in_air", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/downwelling_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/downwelling_spherical_irradiance_in_sea_water.json index 9c5ad4199..1717a4309 100644 --- a/data_descriptors/standard_name/downwelling_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_spherical_irradiance_in_sea_water", + "id": "downwelling_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "downwelling_spherical_irradiance_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Spherical irradiance is the radiation incident on unit area of a hemispherical (or \"2-pi\") collector. It is sometimes called \"scalar irradiance\". The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\".", diff --git a/data_descriptors/standard_name/downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json index 736d7823a..8efcb1f8e 100644 --- a/data_descriptors/standard_name/downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water", + "id": "downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Spherical irradiance is the radiation incident on unit area of a hemispherical (or \"2-pi\") collector. It is sometimes called \"scalar irradiance\". The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\". A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/drainage_amount_through_base_of_soil_model.json b/data_descriptors/standard_name/drainage_amount_through_base_of_soil_model.json index 5e3b20578..b21528bee 100644 --- a/data_descriptors/standard_name/drainage_amount_through_base_of_soil_model.json +++ b/data_descriptors/standard_name/drainage_amount_through_base_of_soil_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/drainage_amount_through_base_of_soil_model", + "id": "drainage_amount_through_base_of_soil_model", "type": "standard_name", "name": "drainage_amount_through_base_of_soil_model", "description": "The quantity with standard name drainage_amount_through_base_of_soil_model is the amount of water that drains through the bottom of a soil column extending from the surface to a specified depth. \"Drainage\" is the process of removal of excess water from soil by gravitational flow. \"Amount\" means mass per unit area. A vertical coordinate variable or scalar coordinate with standard name \"depth\" should be used to specify the depth to which the soil column extends.", diff --git a/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_carbon_dioxide.json b/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_carbon_dioxide.json index b6719d9b9..e47d3eac3 100644 --- a/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dry_atmosphere_mole_fraction_of_carbon_dioxide", + "id": "dry_atmosphere_mole_fraction_of_carbon_dioxide", "type": "standard_name", "name": "dry_atmosphere_mole_fraction_of_carbon_dioxide", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The construction \"dry_atmosphere_mole_fraction\" means that the quantity refers to the whole atmospheric column and is calculated as the total number of particles of X in the column divided by the number of dry air particles in the same column, i.e. the effect of water vapor is excluded. For localized values within the atmospheric medium, standard names including \"in_air\" are used. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_methane.json b/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_methane.json index aeebbc9da..081ed1914 100644 --- a/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_methane.json +++ b/data_descriptors/standard_name/dry_atmosphere_mole_fraction_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dry_atmosphere_mole_fraction_of_methane", + "id": "dry_atmosphere_mole_fraction_of_methane", "type": "standard_name", "name": "dry_atmosphere_mole_fraction_of_methane", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The construction \"dry_atmosphere_mole_fraction\" means that the quantity refers to the whole atmospheric column and is calculated as the total number of particles of X in the column divided by the number of dry air particles in the same column, i.e. the effect of water vapor is excluded. For localized values within the atmospheric medium, standard names including \"in_air\" are used. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/dry_energy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/dry_energy_content_of_atmosphere_layer.json index f1f7346e5..64744d246 100644 --- a/data_descriptors/standard_name/dry_energy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/dry_energy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dry_energy_content_of_atmosphere_layer", + "id": "dry_energy_content_of_atmosphere_layer", "type": "standard_name", "name": "dry_energy_content_of_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/dry_soil_density.json b/data_descriptors/standard_name/dry_soil_density.json index 10f883e6c..f4423a4f1 100644 --- a/data_descriptors/standard_name/dry_soil_density.json +++ b/data_descriptors/standard_name/dry_soil_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dry_soil_density", + "id": "dry_soil_density", "type": "standard_name", "name": "dry_soil_density", "description": "The density of the soil after oven drying until constant mass is reached. Volume is determined from the field sample volume. The density of a substance is its mass per unit volume.", diff --git a/data_descriptors/standard_name/dry_static_energy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/dry_static_energy_content_of_atmosphere_layer.json index d71a92a03..fca3f87e7 100644 --- a/data_descriptors/standard_name/dry_static_energy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/dry_static_energy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dry_static_energy_content_of_atmosphere_layer", + "id": "dry_static_energy_content_of_atmosphere_layer", "type": "standard_name", "name": "dry_static_energy_content_of_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/duration_of_sunshine.json b/data_descriptors/standard_name/duration_of_sunshine.json index 37764716b..84112064b 100644 --- a/data_descriptors/standard_name/duration_of_sunshine.json +++ b/data_descriptors/standard_name/duration_of_sunshine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/duration_of_sunshine", + "id": "duration_of_sunshine", "type": "standard_name", "name": "duration_of_sunshine", "description": "The WMO definition of sunshine is that the surface incident radiative flux from the solar beam (i.e. excluding diffuse skylight) exceeds 120 W m-2. \"Duration\" is the length of time for which a condition holds.", diff --git a/data_descriptors/standard_name/dvorak_tropical_cyclone_current_intensity_number.json b/data_descriptors/standard_name/dvorak_tropical_cyclone_current_intensity_number.json index 99847d762..771bff786 100644 --- a/data_descriptors/standard_name/dvorak_tropical_cyclone_current_intensity_number.json +++ b/data_descriptors/standard_name/dvorak_tropical_cyclone_current_intensity_number.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dvorak_tropical_cyclone_current_intensity_number", + "id": "dvorak_tropical_cyclone_current_intensity_number", "type": "standard_name", "name": "dvorak_tropical_cyclone_current_intensity_number", "description": "\"Dvorak current intensity number\" indicates the ranking of tropical cyclone strength (ranging from 1.0 to 8.0, increasing with storm intensity). The current intensity (CI) number is derived using the Advanced Dvorak Technique based on satellite observations over time. The CI number maps to a maximum sustained 1-minute wind speed and is derived by applying a series of intensity constraints to previous Dvorak-calculated trends of the same storm. Reference: Olander, T. L., & Velden, C. S., The Advanced Dvorak Technique: Continued Development of an Objective Scheme to Estimate Tropical Cyclone Intensity Using Geostationary Infrared Satellite Imagery (2007). American Meteorological Society Weather and Forecasting, 22, 287-298.", diff --git a/data_descriptors/standard_name/dvorak_tropical_number.json b/data_descriptors/standard_name/dvorak_tropical_number.json index 14b9b2e13..6769ee532 100644 --- a/data_descriptors/standard_name/dvorak_tropical_number.json +++ b/data_descriptors/standard_name/dvorak_tropical_number.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dvorak_tropical_number", + "id": "dvorak_tropical_number", "type": "standard_name", "name": "dvorak_tropical_number", "description": "The Advanced Dvorak Technique (ADT) is used to derive a set of Dvorak Tropical numbers using an objective pattern recognition algorithm to determine the intensity of a tropical cyclone by matching observed brightness temperature patterns, maximum sustained winds and minimum sea level pressure to a set of pre-defined tropical cyclone structures. Dvorak Tropical numbers range from 1.0 to 8.0, increasing with storm intensity. Reference: Olander, T. L., & Velden, C. S., The Advanced Dvorak Technique: Continued Development of an Objective Scheme to Estimate Tropical Cyclone Intensity Using Geostationary Infrared Satellite Imagery (2007). American Meteorological Society Weather and Forecasting, 22, 287-298.", diff --git a/data_descriptors/standard_name/dynamic_tropopause_potential_temperature.json b/data_descriptors/standard_name/dynamic_tropopause_potential_temperature.json index db293341b..2e2324cf1 100644 --- a/data_descriptors/standard_name/dynamic_tropopause_potential_temperature.json +++ b/data_descriptors/standard_name/dynamic_tropopause_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/dynamic_tropopause_potential_temperature", + "id": "dynamic_tropopause_potential_temperature", "type": "standard_name", "name": "dynamic_tropopause_potential_temperature", "description": "The dynamical tropopause used in interpreting the dynamics of the upper troposphere and lower stratosphere. There are various definitions of dynamical tropopause in the scientific literature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/eastward_air_velocity_relative_to_sea_water.json b/data_descriptors/standard_name/eastward_air_velocity_relative_to_sea_water.json index c876deb28..4a34ff35d 100644 --- a/data_descriptors/standard_name/eastward_air_velocity_relative_to_sea_water.json +++ b/data_descriptors/standard_name/eastward_air_velocity_relative_to_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_air_velocity_relative_to_sea_water", + "id": "eastward_air_velocity_relative_to_sea_water", "type": "standard_name", "name": "eastward_air_velocity_relative_to_sea_water", "description": "The eastward motion of air, relative to near-surface eastward current; calculated as eastward_wind minus eastward_sea_water_velocity. A vertical coordinate variable or scalar coordinate with standard name \"depth\" should be used to indicate the depth of sea water velocity used in the calculation. Similarly, a vertical coordinate variable or scalar coordinate with standard name \"height\" should be used to indicate the height of the the wind component. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward).", diff --git a/data_descriptors/standard_name/eastward_atmosphere_dry_static_energy_transport_across_unit_distance.json b/data_descriptors/standard_name/eastward_atmosphere_dry_static_energy_transport_across_unit_distance.json index dd67a348b..b3878d869 100644 --- a/data_descriptors/standard_name/eastward_atmosphere_dry_static_energy_transport_across_unit_distance.json +++ b/data_descriptors/standard_name/eastward_atmosphere_dry_static_energy_transport_across_unit_distance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_atmosphere_dry_static_energy_transport_across_unit_distance", + "id": "eastward_atmosphere_dry_static_energy_transport_across_unit_distance", "type": "standard_name", "name": "eastward_atmosphere_dry_static_energy_transport_across_unit_distance", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/eastward_atmosphere_water_transport_across_unit_distance.json b/data_descriptors/standard_name/eastward_atmosphere_water_transport_across_unit_distance.json index 2bed026d0..0f3f8dced 100644 --- a/data_descriptors/standard_name/eastward_atmosphere_water_transport_across_unit_distance.json +++ b/data_descriptors/standard_name/eastward_atmosphere_water_transport_across_unit_distance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_atmosphere_water_transport_across_unit_distance", + "id": "eastward_atmosphere_water_transport_across_unit_distance", "type": "standard_name", "name": "eastward_atmosphere_water_transport_across_unit_distance", "description": "\"Water\" means water in all phases. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.", diff --git a/data_descriptors/standard_name/eastward_atmosphere_water_vapor_transport_across_unit_distance.json b/data_descriptors/standard_name/eastward_atmosphere_water_vapor_transport_across_unit_distance.json index 765637592..370460717 100644 --- a/data_descriptors/standard_name/eastward_atmosphere_water_vapor_transport_across_unit_distance.json +++ b/data_descriptors/standard_name/eastward_atmosphere_water_vapor_transport_across_unit_distance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_atmosphere_water_vapor_transport_across_unit_distance", + "id": "eastward_atmosphere_water_vapor_transport_across_unit_distance", "type": "standard_name", "name": "eastward_atmosphere_water_vapor_transport_across_unit_distance", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.", diff --git a/data_descriptors/standard_name/eastward_derivative_of_eastward_wind.json b/data_descriptors/standard_name/eastward_derivative_of_eastward_wind.json index f008d6f4c..b85efa7fd 100644 --- a/data_descriptors/standard_name/eastward_derivative_of_eastward_wind.json +++ b/data_descriptors/standard_name/eastward_derivative_of_eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_derivative_of_eastward_wind", + "id": "eastward_derivative_of_eastward_wind", "type": "standard_name", "name": "eastward_derivative_of_eastward_wind", "description": "The quantity with standard name eastward_derivative_of_eastward_wind is the derivative of the eastward component of wind with respect to distance in the eastward direction for a given atmospheric level. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/eastward_derivative_of_northward_sea_ice_velocity.json b/data_descriptors/standard_name/eastward_derivative_of_northward_sea_ice_velocity.json index 66809fb1c..172c028ef 100644 --- a/data_descriptors/standard_name/eastward_derivative_of_northward_sea_ice_velocity.json +++ b/data_descriptors/standard_name/eastward_derivative_of_northward_sea_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_derivative_of_northward_sea_ice_velocity", + "id": "eastward_derivative_of_northward_sea_ice_velocity", "type": "standard_name", "name": "eastward_derivative_of_northward_sea_ice_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Sea ice velocity is defined as a two-dimensional vector, with no vertical component. \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. The named quantity is a component of the strain rate tensor for sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/eastward_derivative_of_northward_wind.json b/data_descriptors/standard_name/eastward_derivative_of_northward_wind.json index 5afdb80ea..e48a71bf1 100644 --- a/data_descriptors/standard_name/eastward_derivative_of_northward_wind.json +++ b/data_descriptors/standard_name/eastward_derivative_of_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_derivative_of_northward_wind", + "id": "eastward_derivative_of_northward_wind", "type": "standard_name", "name": "eastward_derivative_of_northward_wind", "description": "The quantity with standard name eastward_derivative_of_northward_wind is the derivative of the northward component of wind with respect to distance in the eastward direction for a given atmospheric level. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/eastward_derivative_of_wind_from_direction.json b/data_descriptors/standard_name/eastward_derivative_of_wind_from_direction.json index 25f8e4fa1..cac113f9c 100644 --- a/data_descriptors/standard_name/eastward_derivative_of_wind_from_direction.json +++ b/data_descriptors/standard_name/eastward_derivative_of_wind_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_derivative_of_wind_from_direction", + "id": "eastward_derivative_of_wind_from_direction", "type": "standard_name", "name": "eastward_derivative_of_wind_from_direction", "description": "The quantity with standard name eastward_derivative_of_wind_from_direction is the derivative of wind from_direction with respect to the change in eastward lateral position for a given atmospheric level. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (\"wind_from_direction\") (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (\"wind_to_direction\") (eastward, southward, etc.). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/eastward_flood_water_velocity.json b/data_descriptors/standard_name/eastward_flood_water_velocity.json index 20e900f86..530f74d39 100644 --- a/data_descriptors/standard_name/eastward_flood_water_velocity.json +++ b/data_descriptors/standard_name/eastward_flood_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_flood_water_velocity", + "id": "eastward_flood_water_velocity", "type": "standard_name", "name": "eastward_flood_water_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/eastward_friction_velocity_at_sea_water_surface.json b/data_descriptors/standard_name/eastward_friction_velocity_at_sea_water_surface.json index 2b9383040..d0511db5f 100644 --- a/data_descriptors/standard_name/eastward_friction_velocity_at_sea_water_surface.json +++ b/data_descriptors/standard_name/eastward_friction_velocity_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_friction_velocity_at_sea_water_surface", + "id": "eastward_friction_velocity_at_sea_water_surface", "type": "standard_name", "name": "eastward_friction_velocity_at_sea_water_surface", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Friction velocity is a reference ocean velocity derived from the relationship between ocean density and downward stress and is usually applied at a level close to the surface where stress is assumed to be independent of height and approximately proportional to the square of mean velocity.", diff --git a/data_descriptors/standard_name/eastward_friction_velocity_in_air.json b/data_descriptors/standard_name/eastward_friction_velocity_in_air.json index ff2f8d4d2..ee2c5e086 100644 --- a/data_descriptors/standard_name/eastward_friction_velocity_in_air.json +++ b/data_descriptors/standard_name/eastward_friction_velocity_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_friction_velocity_in_air", + "id": "eastward_friction_velocity_in_air", "type": "standard_name", "name": "eastward_friction_velocity_in_air", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Friction velocity is a reference wind velocity derived from the relationship between air density and downward stress and is usually applied at a level close to the surface where stress is assumed to independent of height and approximately proportional to the square of mean velocity.", diff --git a/data_descriptors/standard_name/eastward_land_ice_velocity.json b/data_descriptors/standard_name/eastward_land_ice_velocity.json index b7f88d850..6dd166eeb 100644 --- a/data_descriptors/standard_name/eastward_land_ice_velocity.json +++ b/data_descriptors/standard_name/eastward_land_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_land_ice_velocity", + "id": "eastward_land_ice_velocity", "type": "standard_name", "name": "eastward_land_ice_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Land ice velocity is defined as a two-dimensional vector, with no vertical component. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/eastward_mass_flux_of_air.json b/data_descriptors/standard_name/eastward_mass_flux_of_air.json index 95b66d766..a7d7687e0 100644 --- a/data_descriptors/standard_name/eastward_mass_flux_of_air.json +++ b/data_descriptors/standard_name/eastward_mass_flux_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_mass_flux_of_air", + "id": "eastward_mass_flux_of_air", "type": "standard_name", "name": "eastward_mass_flux_of_air", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/eastward_momentum_flux_correction.json b/data_descriptors/standard_name/eastward_momentum_flux_correction.json index 9db82c661..efa098f7c 100644 --- a/data_descriptors/standard_name/eastward_momentum_flux_correction.json +++ b/data_descriptors/standard_name/eastward_momentum_flux_correction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_momentum_flux_correction", + "id": "eastward_momentum_flux_correction", "type": "standard_name", "name": "eastward_momentum_flux_correction", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. Flux correction is also called \"flux adjustment\". A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/eastward_sea_ice_displacement.json b/data_descriptors/standard_name/eastward_sea_ice_displacement.json index 6e249ee18..4ae4c5f2a 100644 --- a/data_descriptors/standard_name/eastward_sea_ice_displacement.json +++ b/data_descriptors/standard_name/eastward_sea_ice_displacement.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_ice_displacement", + "id": "eastward_sea_ice_displacement", "type": "standard_name", "name": "eastward_sea_ice_displacement", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Displacement\" means the change in geospatial position of an object that has moved over time. If possible, the time interval over which the motion took place should be specified using a bounds variable for the time coordinate variable. A displacement can be represented as a vector. Such a vector should however not be interpreted as describing a rectilinear, constant speed motion but merely as an indication that the start point of the vector is found at the tip of the vector after the time interval associated with the displacement variable. A displacement does not prescribe a trajectory. Sea ice displacement can be defined as a two-dimensional vector, with no vertical component. An eastward displacement is the distance calculated from the change in a moving object's longitude between the start and end of the time interval associated with the displacement variable. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/eastward_sea_ice_velocity.json b/data_descriptors/standard_name/eastward_sea_ice_velocity.json index 5b2211271..11569efc3 100644 --- a/data_descriptors/standard_name/eastward_sea_ice_velocity.json +++ b/data_descriptors/standard_name/eastward_sea_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_ice_velocity", + "id": "eastward_sea_ice_velocity", "type": "standard_name", "name": "eastward_sea_ice_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Sea ice velocity is defined as a two-dimensional vector, with no vertical component. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/eastward_sea_water_velocity.json b/data_descriptors/standard_name/eastward_sea_water_velocity.json index 442789246..b20ca7247 100644 --- a/data_descriptors/standard_name/eastward_sea_water_velocity.json +++ b/data_descriptors/standard_name/eastward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_water_velocity", + "id": "eastward_sea_water_velocity", "type": "standard_name", "name": "eastward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward).", diff --git a/data_descriptors/standard_name/eastward_sea_water_velocity_assuming_no_tide.json b/data_descriptors/standard_name/eastward_sea_water_velocity_assuming_no_tide.json index 2d7c20871..f874f6b5a 100644 --- a/data_descriptors/standard_name/eastward_sea_water_velocity_assuming_no_tide.json +++ b/data_descriptors/standard_name/eastward_sea_water_velocity_assuming_no_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_water_velocity_assuming_no_tide", + "id": "eastward_sea_water_velocity_assuming_no_tide", "type": "standard_name", "name": "eastward_sea_water_velocity_assuming_no_tide", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/eastward_sea_water_velocity_at_sea_floor.json b/data_descriptors/standard_name/eastward_sea_water_velocity_at_sea_floor.json index 3b3443ea6..72b686999 100644 --- a/data_descriptors/standard_name/eastward_sea_water_velocity_at_sea_floor.json +++ b/data_descriptors/standard_name/eastward_sea_water_velocity_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_water_velocity_at_sea_floor", + "id": "eastward_sea_water_velocity_at_sea_floor", "type": "standard_name", "name": "eastward_sea_water_velocity_at_sea_floor", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The velocity at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements.", diff --git a/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_ekman_drift.json b/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_ekman_drift.json index 48fd6371c..595943c15 100644 --- a/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_ekman_drift.json +++ b/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_ekman_drift.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_water_velocity_due_to_ekman_drift", + "id": "eastward_sea_water_velocity_due_to_ekman_drift", "type": "standard_name", "name": "eastward_sea_water_velocity_due_to_ekman_drift", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward).The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json b/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json index fe0cef60f..dcdec4156 100644 --- a/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json +++ b/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", + "id": "eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", "type": "standard_name", "name": "eastward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddies occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddies are represented in ocean models using schemes such as the Gent-McWilliams scheme.", diff --git a/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_tides.json b/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_tides.json index 94535967e..dfb9b611d 100644 --- a/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_tides.json +++ b/data_descriptors/standard_name/eastward_sea_water_velocity_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_sea_water_velocity_due_to_tides", + "id": "eastward_sea_water_velocity_due_to_tides", "type": "standard_name", "name": "eastward_sea_water_velocity_due_to_tides", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components.", diff --git a/data_descriptors/standard_name/eastward_transformed_eulerian_mean_air_velocity.json b/data_descriptors/standard_name/eastward_transformed_eulerian_mean_air_velocity.json index 2f4f9e559..19c89d132 100644 --- a/data_descriptors/standard_name/eastward_transformed_eulerian_mean_air_velocity.json +++ b/data_descriptors/standard_name/eastward_transformed_eulerian_mean_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_transformed_eulerian_mean_air_velocity", + "id": "eastward_transformed_eulerian_mean_air_velocity", "type": "standard_name", "name": "eastward_transformed_eulerian_mean_air_velocity", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The \"Transformed Eulerian Mean\" refers to a formulation of the mean equations which incorporates some eddy terms into the definition of the mean, described in Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", diff --git a/data_descriptors/standard_name/eastward_water_vapor_flux_in_air.json b/data_descriptors/standard_name/eastward_water_vapor_flux_in_air.json index ee070edb1..2551700ca 100644 --- a/data_descriptors/standard_name/eastward_water_vapor_flux_in_air.json +++ b/data_descriptors/standard_name/eastward_water_vapor_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_water_vapor_flux_in_air", + "id": "eastward_water_vapor_flux_in_air", "type": "standard_name", "name": "eastward_water_vapor_flux_in_air", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json b/data_descriptors/standard_name/eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json index 0cb90a919..9545bbf39 100644 --- a/data_descriptors/standard_name/eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer", + "id": "eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer", "type": "standard_name", "name": "eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer", "description": "\"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.", diff --git a/data_descriptors/standard_name/eastward_wind.json b/data_descriptors/standard_name/eastward_wind.json index 0167acd4b..cbed235d4 100644 --- a/data_descriptors/standard_name/eastward_wind.json +++ b/data_descriptors/standard_name/eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/eastward_wind", + "id": "eastward_wind", "type": "standard_name", "name": "eastward_wind", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/effective_radius_of_cloud_condensed_water_particles_at_cloud_top.json b/data_descriptors/standard_name/effective_radius_of_cloud_condensed_water_particles_at_cloud_top.json index e59e3b000..05632c0c6 100644 --- a/data_descriptors/standard_name/effective_radius_of_cloud_condensed_water_particles_at_cloud_top.json +++ b/data_descriptors/standard_name/effective_radius_of_cloud_condensed_water_particles_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_cloud_condensed_water_particles_at_cloud_top", + "id": "effective_radius_of_cloud_condensed_water_particles_at_cloud_top", "type": "standard_name", "name": "effective_radius_of_cloud_condensed_water_particles_at_cloud_top", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals,is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. \"cloud_top\" refers to the top of the highest cloud. \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles.json b/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles.json index 94bd17c99..cb30872d9 100644 --- a/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_cloud_liquid_water_particles", + "id": "effective_radius_of_cloud_liquid_water_particles", "type": "standard_name", "name": "effective_radius_of_cloud_liquid_water_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top.json b/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top.json index b7cd08326..3b9360186 100644 --- a/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top.json +++ b/data_descriptors/standard_name/effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top", + "id": "effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top", "type": "standard_name", "name": "effective_radius_of_cloud_liquid_water_particles_at_liquid_water_cloud_top", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The phrase \"cloud_top\" refers to the top of the highest cloud.", diff --git a/data_descriptors/standard_name/effective_radius_of_convective_cloud_ice_particles.json b/data_descriptors/standard_name/effective_radius_of_convective_cloud_ice_particles.json index c53ce4771..486ee186a 100644 --- a/data_descriptors/standard_name/effective_radius_of_convective_cloud_ice_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_convective_cloud_ice_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_convective_cloud_ice_particles", + "id": "effective_radius_of_convective_cloud_ice_particles", "type": "standard_name", "name": "effective_radius_of_convective_cloud_ice_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles.json b/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles.json index 33427402f..0bee6abe1 100644 --- a/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_convective_cloud_liquid_water_particles", + "id": "effective_radius_of_convective_cloud_liquid_water_particles", "type": "standard_name", "name": "effective_radius_of_convective_cloud_liquid_water_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. Convective cloud is that produced by the convection schemes in an atmosphere model. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json b/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json index af7ca2be2..b66fd9511 100644 --- a/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json +++ b/data_descriptors/standard_name/effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top", + "id": "effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top", "type": "standard_name", "name": "effective_radius_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. The phrase \"convective_liquid_water_cloud_top\" refers to the top of the highest convective liquid water cloud. Convective cloud is that produced by the convection schemes in an atmosphere model. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/effective_radius_of_convective_cloud_rain_particles.json b/data_descriptors/standard_name/effective_radius_of_convective_cloud_rain_particles.json index 8d1c0dcf7..74dfd5ce3 100644 --- a/data_descriptors/standard_name/effective_radius_of_convective_cloud_rain_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_convective_cloud_rain_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_convective_cloud_rain_particles", + "id": "effective_radius_of_convective_cloud_rain_particles", "type": "standard_name", "name": "effective_radius_of_convective_cloud_rain_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/effective_radius_of_convective_cloud_snow_particles.json b/data_descriptors/standard_name/effective_radius_of_convective_cloud_snow_particles.json index b94320615..6466acc81 100644 --- a/data_descriptors/standard_name/effective_radius_of_convective_cloud_snow_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_convective_cloud_snow_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_convective_cloud_snow_particles", + "id": "effective_radius_of_convective_cloud_snow_particles", "type": "standard_name", "name": "effective_radius_of_convective_cloud_snow_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_graupel_particles.json b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_graupel_particles.json index e5c0eaed1..52dfe02ef 100644 --- a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_graupel_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_graupel_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_stratiform_cloud_graupel_particles", + "id": "effective_radius_of_stratiform_cloud_graupel_particles", "type": "standard_name", "name": "effective_radius_of_stratiform_cloud_graupel_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", diff --git a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_ice_particles.json b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_ice_particles.json index f2241e3dc..ef417e146 100644 --- a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_ice_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_ice_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_stratiform_cloud_ice_particles", + "id": "effective_radius_of_stratiform_cloud_ice_particles", "type": "standard_name", "name": "effective_radius_of_stratiform_cloud_ice_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", diff --git a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles.json b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles.json index 3545b4182..10c2b0ada 100644 --- a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles", + "id": "effective_radius_of_stratiform_cloud_liquid_water_particles", "type": "standard_name", "name": "effective_radius_of_stratiform_cloud_liquid_water_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json index 27b450afb..ecdd5e651 100644 --- a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json +++ b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top", + "id": "effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top", "type": "standard_name", "name": "effective_radius_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. The phrase \"stratiform_liquid_water_cloud_top\" refers to the top of the highest stratiform liquid water cloud. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_rain_particles.json b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_rain_particles.json index 1f9ef6ab8..c0c4aa9a3 100644 --- a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_rain_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_rain_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_stratiform_cloud_rain_particles", + "id": "effective_radius_of_stratiform_cloud_rain_particles", "type": "standard_name", "name": "effective_radius_of_stratiform_cloud_rain_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", diff --git a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_snow_particles.json b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_snow_particles.json index 48b61492d..3ac350649 100644 --- a/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_snow_particles.json +++ b/data_descriptors/standard_name/effective_radius_of_stratiform_cloud_snow_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/effective_radius_of_stratiform_cloud_snow_particles", + "id": "effective_radius_of_stratiform_cloud_snow_particles", "type": "standard_name", "name": "effective_radius_of_stratiform_cloud_snow_particles", "description": "The effective radius of a size distribution of particles, such as aerosols, cloud droplets or ice crystals, is the area weighted mean radius of particle size. It is calculated as the ratio of the third to the second moment of the particle size distribution. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", diff --git a/data_descriptors/standard_name/electrical_mobility_diameter_of_ambient_aerosol_particles.json b/data_descriptors/standard_name/electrical_mobility_diameter_of_ambient_aerosol_particles.json index 0225a5ce9..3b3bebdc1 100644 --- a/data_descriptors/standard_name/electrical_mobility_diameter_of_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/electrical_mobility_diameter_of_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/electrical_mobility_diameter_of_ambient_aerosol_particles", + "id": "electrical_mobility_diameter_of_ambient_aerosol_particles", "type": "standard_name", "name": "electrical_mobility_diameter_of_ambient_aerosol_particles", "description": "The diameter of an aerosol particle as selected by its electrical mobility. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB.json b/data_descriptors/standard_name/enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB.json index aebb3b3a6..ed1d3a842 100644 --- a/data_descriptors/standard_name/enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB.json +++ b/data_descriptors/standard_name/enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB", + "id": "enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB", "type": "standard_name", "name": "enrichment_of_13C_in_particulate_carbon_in_sea_water_expressed_as_lowercase_delta_13C_relative_to_VPDB", "description": "Isotopic enrichment of 13C, often called delta 13C, is a measure of the ratio of stable isotopes 13C:12C. It is a parameterisation of the 13C/12C isotopic ratio in the sample with respect to the isotopic ratio in a reference standard (in this case Vienna Pee Dee Belemnite). It is computed using the formula (((13C/12C)sample / (13C/12C)standard) - 1) * 1000. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C.json b/data_descriptors/standard_name/enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C.json index 4ba69243d..e1e110e8e 100644 --- a/data_descriptors/standard_name/enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C.json +++ b/data_descriptors/standard_name/enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C", + "id": "enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C", "type": "standard_name", "name": "enrichment_of_14C_in_carbon_dioxide_in_air_expressed_as_uppercase_delta_14C", "description": "Isotopic enrichment of 14C, often called d14C or delta14C (lower case delta), is used to calculate the fossil fuel contribution to atmospheric carbon dioxide using isotopic ratios of carbon. It is a parameterisation of the 14C/12C isotopic ratio in the sample with respect to the isotopic ratio in a reference standard. It is computed using the formula (((14C/12C)sample / (14C/12C)standard) - 1) * 1000. The quantity called D14C, or Delta14C (upper case delta) is d14C corrected for isotopic fractionation using the 13C/12C ratio as follows: D14C = d14C - 2(dC13 + 25)(1+d14C/1000). If the sample is enriched in 14C relative to the standard, then the data value is positive. Reference: Stuiver, M. and H.A. Polach, 1977, Discussion reporting of 14C data, Radiocarbon, Volume 19, No. 3, 355-363, doi: 10.1017/S0033822200003672. The reference standard used in the calculation of delta14C should be specified by attaching a long_name attribute to the data variable. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen.json b/data_descriptors/standard_name/enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen.json index 0882fb24f..c9af3a70d 100644 --- a/data_descriptors/standard_name/enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen.json +++ b/data_descriptors/standard_name/enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen", + "id": "enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen", "type": "standard_name", "name": "enrichment_of_15N_in_particulate_nitrogen_in_sea_water_expressed_as_lowercase_delta_15N_relative_to_atmospheric_nitrogen", "description": "Isotopic enrichment of 15N, often called delta 15N, is a measure of the ratio of stable isotopes 15N:14N. It is a parameterisation of the 15N/14N isotopic ratio in the sample with respect to the isotopic ratio in a reference standard (in this case atmospheric nitrogen). It is computed using the formula (((15N/14N)sample / (15N/14N)standard) - 1) * 1000. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/enthalpy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/enthalpy_content_of_atmosphere_layer.json index d9745b096..b81d274e7 100644 --- a/data_descriptors/standard_name/enthalpy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/enthalpy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/enthalpy_content_of_atmosphere_layer", + "id": "enthalpy_content_of_atmosphere_layer", "type": "standard_name", "name": "enthalpy_content_of_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/equilibrium_line_altitude.json b/data_descriptors/standard_name/equilibrium_line_altitude.json index 8560d7893..d3246147a 100644 --- a/data_descriptors/standard_name/equilibrium_line_altitude.json +++ b/data_descriptors/standard_name/equilibrium_line_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/equilibrium_line_altitude", + "id": "equilibrium_line_altitude", "type": "standard_name", "name": "equilibrium_line_altitude", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. The equilibrium line is the locus of points on a land ice surface at which ice accumulation balances ice ablation over the year.", diff --git a/data_descriptors/standard_name/equivalent_pressure_of_atmosphere_ozone_content.json b/data_descriptors/standard_name/equivalent_pressure_of_atmosphere_ozone_content.json index 819ae01dd..8d030fefd 100644 --- a/data_descriptors/standard_name/equivalent_pressure_of_atmosphere_ozone_content.json +++ b/data_descriptors/standard_name/equivalent_pressure_of_atmosphere_ozone_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/equivalent_pressure_of_atmosphere_ozone_content", + "id": "equivalent_pressure_of_atmosphere_ozone_content", "type": "standard_name", "name": "equivalent_pressure_of_atmosphere_ozone_content", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The equivalent pressure of a particular constituent of the atmosphere is the surface pressure exerted by the weight of that constituent alone.", diff --git a/data_descriptors/standard_name/equivalent_reflectivity_factor.json b/data_descriptors/standard_name/equivalent_reflectivity_factor.json index 77260e06e..542e99b87 100644 --- a/data_descriptors/standard_name/equivalent_reflectivity_factor.json +++ b/data_descriptors/standard_name/equivalent_reflectivity_factor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/equivalent_reflectivity_factor", + "id": "equivalent_reflectivity_factor", "type": "standard_name", "name": "equivalent_reflectivity_factor", "description": "\"Equivalent reflectivity factor\" is the radar reflectivity factor that is calculated from the measured radar return power assuming the target is composed of liquid water droplets whose diameter is less than one tenth of the radar wavelength, i.e., treating the droplets as Rayleigh scatterers. The actual radar reflectivity factor would depend on the size distribution and composition of the particles within the target volume and these are often unknown.", diff --git a/data_descriptors/standard_name/equivalent_thickness_at_stp_of_atmosphere_ozone_content.json b/data_descriptors/standard_name/equivalent_thickness_at_stp_of_atmosphere_ozone_content.json index 48f420842..46cef3819 100644 --- a/data_descriptors/standard_name/equivalent_thickness_at_stp_of_atmosphere_ozone_content.json +++ b/data_descriptors/standard_name/equivalent_thickness_at_stp_of_atmosphere_ozone_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/equivalent_thickness_at_stp_of_atmosphere_ozone_content", + "id": "equivalent_thickness_at_stp_of_atmosphere_ozone_content", "type": "standard_name", "name": "equivalent_thickness_at_stp_of_atmosphere_ozone_content", "description": "\"stp\" means standard temperature (0 degC) and pressure (101325 Pa). \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The equivalent thickness at STP of a particular constituent of the atmosphere is the thickness of the layer that the gas would occupy if it was separated from the other constituents and gathered together at STP. equivalent_thickness_at_stp_of_atmosphere_ozone_content is usually measured in Dobson Units which are equivalent to 446.2 micromoles m-2 or an equivalent thickness at STP of 10 micrometers. N.B. Data variables containing column content of ozone can be given the standard name of either equivalent_thickness_at_stp_of_atmosphere_ozone_content or atmosphere_mole_content_of_ozone. The latter name is recommended for consistency with mole content names for chemical species other than ozone.", diff --git a/data_descriptors/standard_name/ertel_potential_vorticity.json b/data_descriptors/standard_name/ertel_potential_vorticity.json index 3e204f9b7..cb5a28468 100644 --- a/data_descriptors/standard_name/ertel_potential_vorticity.json +++ b/data_descriptors/standard_name/ertel_potential_vorticity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ertel_potential_vorticity", + "id": "ertel_potential_vorticity", "type": "standard_name", "name": "ertel_potential_vorticity", "description": "The Ertel potential vorticity is the scalar product of the atmospheric absolute vorticity vector and the gradient of potential temperature. It is a conserved quantity in the absence of friction and heat sources [AMS Glossary, http://glossary.ametsoc.org/wiki/Ertel_potential_vorticity]. A frequently used simplification of the general Ertel potential vorticity considers the Earth rotation vector to have only a vertical component. Then, only the vertical contribution of the scalar product is calculated. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/fast_soil_pool_mass_content_of_carbon.json b/data_descriptors/standard_name/fast_soil_pool_mass_content_of_carbon.json index a4b008ce5..4ab905347 100644 --- a/data_descriptors/standard_name/fast_soil_pool_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/fast_soil_pool_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fast_soil_pool_mass_content_of_carbon", + "id": "fast_soil_pool_mass_content_of_carbon", "type": "standard_name", "name": "fast_soil_pool_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used. Soil carbon is returned to the atmosphere as the organic matter decays. The decay process takes varying amounts of time depending on the composition of the organic matter, the temperature and the availability of moisture. A carbon \"soil pool\" means the carbon contained in organic matter which has a characteristic period over which it decays and releases carbon into the atmosphere. \"Fast soil pool\" refers to the decay of organic matter in soil with a characteristic period of less than ten years under reference climate conditions of a temperature of 20 degrees Celsius and no water limitations.", diff --git a/data_descriptors/standard_name/final_air_pressure_of_lifted_parcel.json b/data_descriptors/standard_name/final_air_pressure_of_lifted_parcel.json index 9bd1194e4..e7100b3d9 100644 --- a/data_descriptors/standard_name/final_air_pressure_of_lifted_parcel.json +++ b/data_descriptors/standard_name/final_air_pressure_of_lifted_parcel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/final_air_pressure_of_lifted_parcel", + "id": "final_air_pressure_of_lifted_parcel", "type": "standard_name", "name": "final_air_pressure_of_lifted_parcel", "description": "Various stability and convective potential indices are calculated by \"lifting\" a parcel of air: moving it dry adiabatically from a starting height (often the surface) to the Lifting Condensation Level, and then wet adiabatically from there to an ending height (often the top of the data/model/atmosphere). The quantities with standard names original_air_pressure_of_lifted_parcel and final_air_pressure_of_lifted_parcel are the ambient air pressure at the start and end of lifting, respectively. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/fire_area.json b/data_descriptors/standard_name/fire_area.json index 57dd63e01..5e04110b6 100644 --- a/data_descriptors/standard_name/fire_area.json +++ b/data_descriptors/standard_name/fire_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fire_area", + "id": "fire_area", "type": "standard_name", "name": "fire_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\". \"Fire area\" means the area of detected biomass fire.", diff --git a/data_descriptors/standard_name/fire_radiative_power.json b/data_descriptors/standard_name/fire_radiative_power.json index 8d877b863..caa688d65 100644 --- a/data_descriptors/standard_name/fire_radiative_power.json +++ b/data_descriptors/standard_name/fire_radiative_power.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fire_radiative_power", + "id": "fire_radiative_power", "type": "standard_name", "name": "fire_radiative_power", "description": "The product of the irradiance (the power per unit area) of a biomass fire and the corresponding fire area. A data variable containing the area affected by fire should be given the standard name fire_area.", diff --git a/data_descriptors/standard_name/fire_temperature.json b/data_descriptors/standard_name/fire_temperature.json index e057d8c49..288b1cad8 100644 --- a/data_descriptors/standard_name/fire_temperature.json +++ b/data_descriptors/standard_name/fire_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fire_temperature", + "id": "fire_temperature", "type": "standard_name", "name": "fire_temperature", "description": "The overall temperature of a fire area due to contributions from smoldering and flaming biomass. A data variable containing the area affected by fire should be given the standard name fire_area. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/flat_line_test_quality_flag.json b/data_descriptors/standard_name/flat_line_test_quality_flag.json index 0f42961a4..a441b464f 100644 --- a/data_descriptors/standard_name/flat_line_test_quality_flag.json +++ b/data_descriptors/standard_name/flat_line_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/flat_line_test_quality_flag", + "id": "flat_line_test_quality_flag", "type": "standard_name", "name": "flat_line_test_quality_flag", "description": "A quality flag that reports the result of the Flat Line test, which checks for consecutively repeated values within a tolerance. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/floating_ice_shelf_area.json b/data_descriptors/standard_name/floating_ice_shelf_area.json index 30f2f15de..1b74b9d93 100644 --- a/data_descriptors/standard_name/floating_ice_shelf_area.json +++ b/data_descriptors/standard_name/floating_ice_shelf_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/floating_ice_shelf_area", + "id": "floating_ice_shelf_area", "type": "standard_name", "name": "floating_ice_shelf_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\". A \"floating ice shelf\", sometimes called a \"floating ice sheet\", indicates where an ice sheet extending from a land area flows over sea water.", diff --git a/data_descriptors/standard_name/floating_ice_shelf_area_fraction.json b/data_descriptors/standard_name/floating_ice_shelf_area_fraction.json index 53c110196..f9662c2cc 100644 --- a/data_descriptors/standard_name/floating_ice_shelf_area_fraction.json +++ b/data_descriptors/standard_name/floating_ice_shelf_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/floating_ice_shelf_area_fraction", + "id": "floating_ice_shelf_area_fraction", "type": "standard_name", "name": "floating_ice_shelf_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. A \"floating ice shelf\", sometimes called a \"floating ice sheet\", indicates where an ice sheet extending from a land area flows over sea water.", diff --git a/data_descriptors/standard_name/floating_ice_thickness.json b/data_descriptors/standard_name/floating_ice_thickness.json index cf157bfe0..7eeb246a0 100644 --- a/data_descriptors/standard_name/floating_ice_thickness.json +++ b/data_descriptors/standard_name/floating_ice_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/floating_ice_thickness", + "id": "floating_ice_thickness", "type": "standard_name", "name": "floating_ice_thickness", "description": "\"Floating ice\" means any ice that is floating on water, e.g. on a sea or lake surface. \"Thickness\" means the vertical extent of the ice.", diff --git a/data_descriptors/standard_name/flood_water_duration_above_threshold.json b/data_descriptors/standard_name/flood_water_duration_above_threshold.json index 3ea25b02e..f697b17a0 100644 --- a/data_descriptors/standard_name/flood_water_duration_above_threshold.json +++ b/data_descriptors/standard_name/flood_water_duration_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/flood_water_duration_above_threshold", + "id": "flood_water_duration_above_threshold", "type": "standard_name", "name": "flood_water_duration_above_threshold", "description": "The quantity with standard name flood_water_duration_above_threshold is the time elapsed between the instant when the flood depth first rises above a given threshold until the time falls below the same threshold for the last time at a given point in space. If a threshold is supplied, it should be specified by associating a coordinate variable or scalar coordinate variable with the data variable and giving the coordinate variable a standard name of flood_water_thickness. The values of the coordinate variable are the threshold values for the corresponding subarrays of the data variable. If no threshold is specified, its value is taken to be zero. Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/flood_water_speed.json b/data_descriptors/standard_name/flood_water_speed.json index 7fa90d261..54034b778 100644 --- a/data_descriptors/standard_name/flood_water_speed.json +++ b/data_descriptors/standard_name/flood_water_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/flood_water_speed", + "id": "flood_water_speed", "type": "standard_name", "name": "flood_water_speed", "description": "Speed is the magnitude of velocity. Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/flood_water_thickness.json b/data_descriptors/standard_name/flood_water_thickness.json index 4d6176052..8b10df57e 100644 --- a/data_descriptors/standard_name/flood_water_thickness.json +++ b/data_descriptors/standard_name/flood_water_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/flood_water_thickness", + "id": "flood_water_thickness", "type": "standard_name", "name": "flood_water_thickness", "description": "The flood_water_thickness is the vertical distance between the surface of the flood water and the surface of the solid ground, as measured at a given point in space. The standard name ground_level_altitude is used for a data variable giving the geometric height of the ground surface above the geoid. \"Flood water\" is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/fog_area_fraction.json b/data_descriptors/standard_name/fog_area_fraction.json index d6f607b64..f8558ecc8 100644 --- a/data_descriptors/standard_name/fog_area_fraction.json +++ b/data_descriptors/standard_name/fog_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fog_area_fraction", + "id": "fog_area_fraction", "type": "standard_name", "name": "fog_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Fog means water droplets or minute ice crystals close to the surface which reduce visibility in air to less than 1000m.", diff --git a/data_descriptors/standard_name/forecast_period.json b/data_descriptors/standard_name/forecast_period.json index 9af950c97..0764017ac 100644 --- a/data_descriptors/standard_name/forecast_period.json +++ b/data_descriptors/standard_name/forecast_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/forecast_period", + "id": "forecast_period", "type": "standard_name", "name": "forecast_period", "description": "Forecast period is the time interval between the forecast reference time and the validity time. A period is an interval of time, or the time-period of an oscillation.", diff --git a/data_descriptors/standard_name/forecast_reference_time.json b/data_descriptors/standard_name/forecast_reference_time.json index 6c9bbd12c..22b458d05 100644 --- a/data_descriptors/standard_name/forecast_reference_time.json +++ b/data_descriptors/standard_name/forecast_reference_time.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/forecast_reference_time", + "id": "forecast_reference_time", "type": "standard_name", "name": "forecast_reference_time", "description": "The forecast reference time in NWP is the \"data time\", the time of the analysis from which the forecast was made. It is not the time for which the forecast is valid; the standard name of time should be used for that time.", diff --git a/data_descriptors/standard_name/fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation.json b/data_descriptors/standard_name/fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation.json index 92517e823..9f49f6c5c 100644 --- a/data_descriptors/standard_name/fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation.json +++ b/data_descriptors/standard_name/fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation", + "id": "fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation", "type": "standard_name", "name": "fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The surface called \"surface\" means the lower boundary of the atmosphere. The quantity with standard name fraction_of_surface_downwelling_photosynthetic_radiative_flux_absorbed_by_vegetation, often called Fraction of Absorbed Photosynthetically Active Radiation (FAPAR), is the fraction of incoming solar radiation in the photosynthetically active radiation spectral region that is absorbed by a vegetation canopy. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of \"radiation_wavelength\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/fraction_of_time_with_sea_ice_area_fraction_above_threshold.json b/data_descriptors/standard_name/fraction_of_time_with_sea_ice_area_fraction_above_threshold.json index 859b5a323..6380e92bb 100644 --- a/data_descriptors/standard_name/fraction_of_time_with_sea_ice_area_fraction_above_threshold.json +++ b/data_descriptors/standard_name/fraction_of_time_with_sea_ice_area_fraction_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fraction_of_time_with_sea_ice_area_fraction_above_threshold", + "id": "fraction_of_time_with_sea_ice_area_fraction_above_threshold", "type": "standard_name", "name": "fraction_of_time_with_sea_ice_area_fraction_above_threshold", "description": "\"Fraction of time\" is the fraction of a time period defined by the bounds of the time coordinate variable for which a characteristic of interest exists. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Sea ice area fraction is area of the sea surface occupied by sea ice. The area threshold value must be specified by supplying a coordinate variable or scalar coordinate variable with the standard name of sea_ice_area_fraction. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/fractional_saturation_of_oxygen_in_sea_water.json b/data_descriptors/standard_name/fractional_saturation_of_oxygen_in_sea_water.json index 66fb53d08..01f9f009d 100644 --- a/data_descriptors/standard_name/fractional_saturation_of_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/fractional_saturation_of_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fractional_saturation_of_oxygen_in_sea_water", + "id": "fractional_saturation_of_oxygen_in_sea_water", "type": "standard_name", "name": "fractional_saturation_of_oxygen_in_sea_water", "description": "Fractional saturation is the ratio of some measure of concentration to the saturated value of the same quantity.", diff --git a/data_descriptors/standard_name/freezing_level_altitude.json b/data_descriptors/standard_name/freezing_level_altitude.json index 72dcc2e11..8ecd3fd54 100644 --- a/data_descriptors/standard_name/freezing_level_altitude.json +++ b/data_descriptors/standard_name/freezing_level_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/freezing_level_altitude", + "id": "freezing_level_altitude", "type": "standard_name", "name": "freezing_level_altitude", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/freezing_temperature_of_sea_water.json b/data_descriptors/standard_name/freezing_temperature_of_sea_water.json index ab8e4a08a..ef0dfbcae 100644 --- a/data_descriptors/standard_name/freezing_temperature_of_sea_water.json +++ b/data_descriptors/standard_name/freezing_temperature_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/freezing_temperature_of_sea_water", + "id": "freezing_temperature_of_sea_water", "type": "standard_name", "name": "freezing_temperature_of_sea_water", "description": null, diff --git a/data_descriptors/standard_name/frequency_of_lightning_flashes_per_unit_area.json b/data_descriptors/standard_name/frequency_of_lightning_flashes_per_unit_area.json index f4eee5cc5..630c41ee6 100644 --- a/data_descriptors/standard_name/frequency_of_lightning_flashes_per_unit_area.json +++ b/data_descriptors/standard_name/frequency_of_lightning_flashes_per_unit_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/frequency_of_lightning_flashes_per_unit_area", + "id": "frequency_of_lightning_flashes_per_unit_area", "type": "standard_name", "name": "frequency_of_lightning_flashes_per_unit_area", "description": "A lightning flash is a compound event, usually consisting of several discharges. Frequency is the number of oscillations of a wave, or the number of occurrences of an event, per unit time.", diff --git a/data_descriptors/standard_name/frozen_soil_density.json b/data_descriptors/standard_name/frozen_soil_density.json index 7ab1427f1..0520de04a 100644 --- a/data_descriptors/standard_name/frozen_soil_density.json +++ b/data_descriptors/standard_name/frozen_soil_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/frozen_soil_density", + "id": "frozen_soil_density", "type": "standard_name", "name": "frozen_soil_density", "description": "The density of the soil in its naturally frozen condition. Also known as frozen bulk density. The density of a substance is its mass per unit volume.", diff --git a/data_descriptors/standard_name/frozen_water_content_of_soil_layer.json b/data_descriptors/standard_name/frozen_water_content_of_soil_layer.json index a82f2cee1..096ff41d3 100644 --- a/data_descriptors/standard_name/frozen_water_content_of_soil_layer.json +++ b/data_descriptors/standard_name/frozen_water_content_of_soil_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/frozen_water_content_of_soil_layer", + "id": "frozen_water_content_of_soil_layer", "type": "standard_name", "name": "frozen_water_content_of_soil_layer", "description": "\"frozen_water\" means ice. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).", diff --git a/data_descriptors/standard_name/fugacity_of_carbon_dioxide_in_sea_water.json b/data_descriptors/standard_name/fugacity_of_carbon_dioxide_in_sea_water.json index cc7001c66..f69fff859 100644 --- a/data_descriptors/standard_name/fugacity_of_carbon_dioxide_in_sea_water.json +++ b/data_descriptors/standard_name/fugacity_of_carbon_dioxide_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/fugacity_of_carbon_dioxide_in_sea_water", + "id": "fugacity_of_carbon_dioxide_in_sea_water", "type": "standard_name", "name": "fugacity_of_carbon_dioxide_in_sea_water", "description": "The fugacity is the measured pressure (or partial pressure) of a real gas corrected for the intermolecular forces of that gas, which allows that corrected quantity to be treated like the pressure of an ideal gas in the ideal gas equation PV = nRT. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/gap_test_quality_flag.json b/data_descriptors/standard_name/gap_test_quality_flag.json index 066b20000..de9bf2c4b 100644 --- a/data_descriptors/standard_name/gap_test_quality_flag.json +++ b/data_descriptors/standard_name/gap_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gap_test_quality_flag", + "id": "gap_test_quality_flag", "type": "standard_name", "name": "gap_test_quality_flag", "description": "A quality flag that reports the result of the Timing/Gap test, which checks that data have been received within the expected time window and have the correct time stamp. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/geoid_height_above_reference_ellipsoid.json b/data_descriptors/standard_name/geoid_height_above_reference_ellipsoid.json index 20fa24687..f2b8f6fef 100644 --- a/data_descriptors/standard_name/geoid_height_above_reference_ellipsoid.json +++ b/data_descriptors/standard_name/geoid_height_above_reference_ellipsoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geoid_height_above_reference_ellipsoid", + "id": "geoid_height_above_reference_ellipsoid", "type": "standard_name", "name": "geoid_height_above_reference_ellipsoid", "description": "The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/geopotential.json b/data_descriptors/standard_name/geopotential.json index 94c84ef10..a81312968 100644 --- a/data_descriptors/standard_name/geopotential.json +++ b/data_descriptors/standard_name/geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geopotential", + "id": "geopotential", "type": "standard_name", "name": "geopotential", "description": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy.", diff --git a/data_descriptors/standard_name/geopotential_height.json b/data_descriptors/standard_name/geopotential_height.json index 253579184..94d018388 100644 --- a/data_descriptors/standard_name/geopotential_height.json +++ b/data_descriptors/standard_name/geopotential_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geopotential_height", + "id": "geopotential_height", "type": "standard_name", "name": "geopotential_height", "description": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", diff --git a/data_descriptors/standard_name/geopotential_height_anomaly.json b/data_descriptors/standard_name/geopotential_height_anomaly.json index c4a3017ff..6dfbbee11 100644 --- a/data_descriptors/standard_name/geopotential_height_anomaly.json +++ b/data_descriptors/standard_name/geopotential_height_anomaly.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geopotential_height_anomaly", + "id": "geopotential_height_anomaly", "type": "standard_name", "name": "geopotential_height_anomaly", "description": "\"anomaly\" means difference from climatology. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", diff --git a/data_descriptors/standard_name/geopotential_height_at_cloud_top.json b/data_descriptors/standard_name/geopotential_height_at_cloud_top.json index fed520ac4..a96f0742c 100644 --- a/data_descriptors/standard_name/geopotential_height_at_cloud_top.json +++ b/data_descriptors/standard_name/geopotential_height_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geopotential_height_at_cloud_top", + "id": "geopotential_height_at_cloud_top", "type": "standard_name", "name": "geopotential_height_at_cloud_top", "description": "Cloud_top refers to the top of the highest cloud. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name \"height\", which is relative to the surface.", diff --git a/data_descriptors/standard_name/geopotential_height_at_volcanic_ash_cloud_top.json b/data_descriptors/standard_name/geopotential_height_at_volcanic_ash_cloud_top.json index 28f3f4299..e8ee0e2c3 100644 --- a/data_descriptors/standard_name/geopotential_height_at_volcanic_ash_cloud_top.json +++ b/data_descriptors/standard_name/geopotential_height_at_volcanic_ash_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geopotential_height_at_volcanic_ash_cloud_top", + "id": "geopotential_height_at_volcanic_ash_cloud_top", "type": "standard_name", "name": "geopotential_height_at_volcanic_ash_cloud_top", "description": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name \"height\", which is relative to the surface. \"Volcanic_ash\" means the fine-grained products of explosive volcanic eruptions, such as minerals or crystals, older fragmented rock (e.g. andesite), and glass. Particles within a volcanic ash cloud have diameters less than 2 mm. \"Volcanic_ash\" does not include non-volcanic dust.", diff --git a/data_descriptors/standard_name/geostrophic_eastward_sea_water_velocity.json b/data_descriptors/standard_name/geostrophic_eastward_sea_water_velocity.json index 5f6fc46e6..359fd5b7f 100644 --- a/data_descriptors/standard_name/geostrophic_eastward_sea_water_velocity.json +++ b/data_descriptors/standard_name/geostrophic_eastward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geostrophic_eastward_sea_water_velocity", + "id": "geostrophic_eastward_sea_water_velocity", "type": "standard_name", "name": "geostrophic_eastward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars.", diff --git a/data_descriptors/standard_name/geostrophic_eastward_wind.json b/data_descriptors/standard_name/geostrophic_eastward_wind.json index 1a73828aa..b8a2c6252 100644 --- a/data_descriptors/standard_name/geostrophic_eastward_wind.json +++ b/data_descriptors/standard_name/geostrophic_eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geostrophic_eastward_wind", + "id": "geostrophic_eastward_wind", "type": "standard_name", "name": "geostrophic_eastward_wind", "description": "\"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars.", diff --git a/data_descriptors/standard_name/geostrophic_northward_sea_water_velocity.json b/data_descriptors/standard_name/geostrophic_northward_sea_water_velocity.json index bbd8a435e..93902fe7d 100644 --- a/data_descriptors/standard_name/geostrophic_northward_sea_water_velocity.json +++ b/data_descriptors/standard_name/geostrophic_northward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geostrophic_northward_sea_water_velocity", + "id": "geostrophic_northward_sea_water_velocity", "type": "standard_name", "name": "geostrophic_northward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars.", diff --git a/data_descriptors/standard_name/geostrophic_northward_wind.json b/data_descriptors/standard_name/geostrophic_northward_wind.json index cf98c2213..a0844208a 100644 --- a/data_descriptors/standard_name/geostrophic_northward_wind.json +++ b/data_descriptors/standard_name/geostrophic_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/geostrophic_northward_wind", + "id": "geostrophic_northward_wind", "type": "standard_name", "name": "geostrophic_northward_wind", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars.", diff --git a/data_descriptors/standard_name/global_average_sea_level_change.json b/data_descriptors/standard_name/global_average_sea_level_change.json index 0b7193160..8b359911e 100644 --- a/data_descriptors/standard_name/global_average_sea_level_change.json +++ b/data_descriptors/standard_name/global_average_sea_level_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/global_average_sea_level_change", + "id": "global_average_sea_level_change", "type": "standard_name", "name": "global_average_sea_level_change", "description": "Global average sea level change is due to change in volume of the water in the ocean, caused by mass and/or density change, or to change in the volume of the ocean basins, caused by tectonics etc. It is sometimes called \"eustatic\", which is a term that also has other definitions. It differs from the change in the global average sea surface height relative to the centre of the Earth by the global average vertical movement of the ocean floor. Zero sea level change is an arbitrary level. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level.", diff --git a/data_descriptors/standard_name/global_average_sea_level_change_due_to_change_in_ocean_mass.json b/data_descriptors/standard_name/global_average_sea_level_change_due_to_change_in_ocean_mass.json index cf2610e2e..3a0ee0c9a 100644 --- a/data_descriptors/standard_name/global_average_sea_level_change_due_to_change_in_ocean_mass.json +++ b/data_descriptors/standard_name/global_average_sea_level_change_due_to_change_in_ocean_mass.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/global_average_sea_level_change_due_to_change_in_ocean_mass", + "id": "global_average_sea_level_change_due_to_change_in_ocean_mass", "type": "standard_name", "name": "global_average_sea_level_change_due_to_change_in_ocean_mass", "description": "Global average mass volume sea level change is caused by water mass balance (evaporation \u2013 precipitation + runoff). This in turn results in a change in volume of the world ocean. Zero sea level change is an arbitrary level. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level. This quantity is sometimes called \"barystatic sea level rise\" or \"barystatic sea level change\". It is the part of global-mean sea-level rise which is due to the addition to the ocean of water mass that formerly resided within the land area (as land water storage or land ice) or in the atmosphere (which contains a relatively tiny mass of water).", diff --git a/data_descriptors/standard_name/global_average_steric_sea_level_change.json b/data_descriptors/standard_name/global_average_steric_sea_level_change.json index 7768d84b8..a430b4521 100644 --- a/data_descriptors/standard_name/global_average_steric_sea_level_change.json +++ b/data_descriptors/standard_name/global_average_steric_sea_level_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/global_average_steric_sea_level_change", + "id": "global_average_steric_sea_level_change", "type": "standard_name", "name": "global_average_steric_sea_level_change", "description": "Global average steric sea level change is caused by changes in sea water density due to changes in temperature (thermosteric) and salinity (halosteric). This in turn results in a change in volume of the world ocean. Zero sea level change is an arbitrary level. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level.", diff --git a/data_descriptors/standard_name/global_average_thermosteric_sea_level_change.json b/data_descriptors/standard_name/global_average_thermosteric_sea_level_change.json index 9037c1e72..007fb6424 100644 --- a/data_descriptors/standard_name/global_average_thermosteric_sea_level_change.json +++ b/data_descriptors/standard_name/global_average_thermosteric_sea_level_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/global_average_thermosteric_sea_level_change", + "id": "global_average_thermosteric_sea_level_change", "type": "standard_name", "name": "global_average_thermosteric_sea_level_change", "description": "Global average thermosteric sea level change is the part caused by change in density due to change in temperature i.e. thermal expansion. This in turn results in a change in volume of the world ocean. Zero sea level change is an arbitrary level. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level.", diff --git a/data_descriptors/standard_name/graupel_and_hail_fall_amount.json b/data_descriptors/standard_name/graupel_and_hail_fall_amount.json index 3ac00b7cb..3f4619cbf 100644 --- a/data_descriptors/standard_name/graupel_and_hail_fall_amount.json +++ b/data_descriptors/standard_name/graupel_and_hail_fall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/graupel_and_hail_fall_amount", + "id": "graupel_and_hail_fall_amount", "type": "standard_name", "name": "graupel_and_hail_fall_amount", "description": "\"Amount\" means mass per unit area. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel. For models that do distinguish between them, separate standard names for hail and graupel are available.", diff --git a/data_descriptors/standard_name/graupel_and_hail_fall_flux.json b/data_descriptors/standard_name/graupel_and_hail_fall_flux.json index 58ae2adb0..25cc84968 100644 --- a/data_descriptors/standard_name/graupel_and_hail_fall_flux.json +++ b/data_descriptors/standard_name/graupel_and_hail_fall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/graupel_and_hail_fall_flux", + "id": "graupel_and_hail_fall_flux", "type": "standard_name", "name": "graupel_and_hail_fall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel. For models that do distinguish between them, separate standard names for hail and graupel are available.", diff --git a/data_descriptors/standard_name/graupel_fall_amount.json b/data_descriptors/standard_name/graupel_fall_amount.json index 37048246e..ce83f7a5c 100644 --- a/data_descriptors/standard_name/graupel_fall_amount.json +++ b/data_descriptors/standard_name/graupel_fall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/graupel_fall_amount", + "id": "graupel_fall_amount", "type": "standard_name", "name": "graupel_fall_amount", "description": "\"Amount\" means mass per unit area. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except for the size convention that hail must have a diameter greater than 5 mm. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel.", diff --git a/data_descriptors/standard_name/graupel_fall_flux.json b/data_descriptors/standard_name/graupel_fall_flux.json index 5db74106d..6063bdb82 100644 --- a/data_descriptors/standard_name/graupel_fall_flux.json +++ b/data_descriptors/standard_name/graupel_fall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/graupel_fall_flux", + "id": "graupel_fall_flux", "type": "standard_name", "name": "graupel_fall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. There are also separate standard names for hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/grid_latitude.json b/data_descriptors/standard_name/grid_latitude.json index 8056291d5..7d40b2b52 100644 --- a/data_descriptors/standard_name/grid_latitude.json +++ b/data_descriptors/standard_name/grid_latitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/grid_latitude", + "id": "grid_latitude", "type": "standard_name", "name": "grid_latitude", "description": "Latitude is positive northward; its units of degree_north (or equivalent) indicate this explicitly. In a latitude-longitude system defined with respect to a rotated North Pole, the standard name of grid_latitude should be used instead of latitude. Grid latitude is positive in the grid-northward direction, but its units should be plain degree.", diff --git a/data_descriptors/standard_name/grid_longitude.json b/data_descriptors/standard_name/grid_longitude.json index 4b0db21dc..10eec4226 100644 --- a/data_descriptors/standard_name/grid_longitude.json +++ b/data_descriptors/standard_name/grid_longitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/grid_longitude", + "id": "grid_longitude", "type": "standard_name", "name": "grid_longitude", "description": "Longitude is positive eastward; its units of degree_east (or equivalent) indicate this explicitly. In a latitude-longitude system defined with respect to a rotated North Pole, the standard name of grid_longitude should be used instead of longitude. Grid longitude is positive in the grid-eastward direction, but its units should be plain degree.", diff --git a/data_descriptors/standard_name/gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json b/data_descriptors/standard_name/gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json index cc5c84caa..4cee4c491 100644 --- a/data_descriptors/standard_name/gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json +++ b/data_descriptors/standard_name/gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water", + "id": "gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water", "type": "standard_name", "name": "gross_mole_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water", "description": "\"Gross mole production\" means the rate of creation of biomass per unit volume with no correction for respiration loss in terms of quantity of matter (moles). The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Prokaryotes\" means all Bacteria and Archaea excluding photosynthetic cyanobacteria such as Synechococcus and Prochlorococcus or other separately named components of the prokaryotic population.", diff --git a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_13C.json b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_13C.json index 4ecbf43c9..15635e40b 100644 --- a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_13C.json +++ b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_13C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_primary_productivity_of_biomass_expressed_as_13C", + "id": "gross_primary_productivity_of_biomass_expressed_as_13C", "type": "standard_name", "name": "gross_primary_productivity_of_biomass_expressed_as_13C", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Gross primary production is the rate of synthesis of biomass from inorganic precursors by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is \"net_primary_production\". \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_14C.json b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_14C.json index 0432586e5..12ebf32dc 100644 --- a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_14C.json +++ b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_14C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_primary_productivity_of_biomass_expressed_as_14C", + "id": "gross_primary_productivity_of_biomass_expressed_as_14C", "type": "standard_name", "name": "gross_primary_productivity_of_biomass_expressed_as_14C", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Gross primary production is the rate of synthesis of biomass from inorganic precursors by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is \"net_primary_production\". \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon.json b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon.json index 9aa77f3e4..b737ce277 100644 --- a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon.json +++ b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon", + "id": "gross_primary_productivity_of_biomass_expressed_as_carbon", "type": "standard_name", "name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Gross primary production is the rate of synthesis of biomass from inorganic precursors by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is \"net_primary_production\". \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice.json b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice.json index 2a5d6a335..41c67efba 100644 --- a/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice.json +++ b/data_descriptors/standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice", + "id": "gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice", "type": "standard_name", "name": "gross_primary_productivity_of_biomass_expressed_as_carbon_due_to_ice_algae_in_sea_ice", "description": "Total GPP of ice algae in sea ice. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Gross primary production is the rate of synthesis of biomass from inorganic precursors by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is \"net_primary_production\". \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. Sea-ice algae (or simply 'ice algae' when the context of sea ice is clear) refer to algae uniquely able to thrive within the sea-ice environment. This distinction from phytoplankton is essential, as several phytoplankton species that become trapped in sea ice eventually perish due to a lack of genetic adaptation or acclimation strategies to survive such conditions. By referring to 'sea-ice algae,' we highlight these algae's specific features and ecological significance within the sea-ice habitat.", diff --git a/data_descriptors/standard_name/gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json b/data_descriptors/standard_name/gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json index f28582579..81f6ec83f 100644 --- a/data_descriptors/standard_name/gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json +++ b/data_descriptors/standard_name/gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water", + "id": "gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water", "type": "standard_name", "name": "gross_production_of_biomass_expressed_as_carbon_by_prokaryotes_in_sea_water", "description": "\"Gross production\" means the rate of creation of biomass per unit volume with no correction for respiration. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Prokaryotes\" means all Bacteria and Archaea excluding photosynthetic cyanobacteria such as Synechococcus and Prochlorococcus or other separately named components of the prokaryotic population.", diff --git a/data_descriptors/standard_name/gross_range_test_quality_flag.json b/data_descriptors/standard_name/gross_range_test_quality_flag.json index f84203ea5..2002ec1ba 100644 --- a/data_descriptors/standard_name/gross_range_test_quality_flag.json +++ b/data_descriptors/standard_name/gross_range_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_range_test_quality_flag", + "id": "gross_range_test_quality_flag", "type": "standard_name", "name": "gross_range_test_quality_flag", "description": "A quality flag that reports the result of the Gross Range test, which checks that values are within reasonable range bounds. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/gross_rate_of_decrease_in_area_fraction.json b/data_descriptors/standard_name/gross_rate_of_decrease_in_area_fraction.json index 1e4436087..ff2ea04ee 100644 --- a/data_descriptors/standard_name/gross_rate_of_decrease_in_area_fraction.json +++ b/data_descriptors/standard_name/gross_rate_of_decrease_in_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_rate_of_decrease_in_area_fraction", + "id": "gross_rate_of_decrease_in_area_fraction", "type": "standard_name", "name": "gross_rate_of_decrease_in_area_fraction", "description": "The \"gross rate of decrease in area fraction\" is the fraction of a grid cell that transitions from a given area type per unit time, for example, as a result of land use changes. The quantity described by this standard name is a gross decrease because it includes only land where the use transitions away from the given area type and excludes land that transitions to that area type during the same period. The area type should be specified using a coordinate of scalar coordinate variable with standard name area_type. There is also a standard name for gross_rate_of_increase_in_area_fraction. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/gross_rate_of_increase_in_area_fraction.json b/data_descriptors/standard_name/gross_rate_of_increase_in_area_fraction.json index a405fd2e2..2151bbbe2 100644 --- a/data_descriptors/standard_name/gross_rate_of_increase_in_area_fraction.json +++ b/data_descriptors/standard_name/gross_rate_of_increase_in_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/gross_rate_of_increase_in_area_fraction", + "id": "gross_rate_of_increase_in_area_fraction", "type": "standard_name", "name": "gross_rate_of_increase_in_area_fraction", "description": "The \"rate of increase in area fraction\" is the fraction of a grid cell that transitions to a given area type per unit time, for example, as a result of land use changes. The quantity described by this standard name is a gross increase because it includes only land where the use transitions to the given area type and excludes land that transitions away from that area type during the same period. The area type should be specified using a coordinate or scalar coordinate variable with standard name area_type. There is also a standard name for gross_rate_of_decrease_in_area_fraction. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/ground_level_altitude.json b/data_descriptors/standard_name/ground_level_altitude.json index 6ee21eab2..7e6bb9215 100644 --- a/data_descriptors/standard_name/ground_level_altitude.json +++ b/data_descriptors/standard_name/ground_level_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ground_level_altitude", + "id": "ground_level_altitude", "type": "standard_name", "name": "ground_level_altitude", "description": "The ground_level_altitude is the geometric height of the upper boundary of the solid Earth above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/ground_slope_angle.json b/data_descriptors/standard_name/ground_slope_angle.json index 3b22da575..93ef44726 100644 --- a/data_descriptors/standard_name/ground_slope_angle.json +++ b/data_descriptors/standard_name/ground_slope_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ground_slope_angle", + "id": "ground_slope_angle", "type": "standard_name", "name": "ground_slope_angle", "description": "The slope angle is the angle (in degrees) measured between the ground (earth) surface plane and a flat, horizontal surface.", diff --git a/data_descriptors/standard_name/ground_slope_direction.json b/data_descriptors/standard_name/ground_slope_direction.json index 04d592f78..3495232d8 100644 --- a/data_descriptors/standard_name/ground_slope_direction.json +++ b/data_descriptors/standard_name/ground_slope_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ground_slope_direction", + "id": "ground_slope_direction", "type": "standard_name", "name": "ground_slope_direction", "description": "Commonly known as aspect, it is the azimuth (in degrees) of a terrain slope, taken as the direction with the greatest downslope change in elevation on the ground (earth) surface. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/grounded_ice_sheet_area.json b/data_descriptors/standard_name/grounded_ice_sheet_area.json index 2f11ac3d1..de23cbac1 100644 --- a/data_descriptors/standard_name/grounded_ice_sheet_area.json +++ b/data_descriptors/standard_name/grounded_ice_sheet_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/grounded_ice_sheet_area", + "id": "grounded_ice_sheet_area", "type": "standard_name", "name": "grounded_ice_sheet_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\". \"Grounded ice sheet\" indicates where the ice sheet rests over bedrock and is thus grounded. It excludes ice-caps, glaciers and floating ice shelves.", diff --git a/data_descriptors/standard_name/grounded_ice_sheet_area_fraction.json b/data_descriptors/standard_name/grounded_ice_sheet_area_fraction.json index 3cb87b73a..47811c817 100644 --- a/data_descriptors/standard_name/grounded_ice_sheet_area_fraction.json +++ b/data_descriptors/standard_name/grounded_ice_sheet_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/grounded_ice_sheet_area_fraction", + "id": "grounded_ice_sheet_area_fraction", "type": "standard_name", "name": "grounded_ice_sheet_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Grounded ice sheet\" indicates where the ice sheet rests over bedrock and is thus grounded. It excludes ice-caps, glaciers and floating ice shelves.", diff --git a/data_descriptors/standard_name/growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance.json b/data_descriptors/standard_name/growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance.json index 26988c6a4..6bea9daf4 100644 --- a/data_descriptors/standard_name/growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance.json +++ b/data_descriptors/standard_name/growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance", + "id": "growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance", "type": "standard_name", "name": "growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance", "description": "\"Calcareous phytoplankton\" are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy. Solar irradiance is essential to the photosynthesis reaction and its presence promotes the growth of phytoplankton populations. \"Growth limitation due to solar irradiance\" means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", diff --git a/data_descriptors/standard_name/growth_limitation_of_diatoms_due_to_solar_irradiance.json b/data_descriptors/standard_name/growth_limitation_of_diatoms_due_to_solar_irradiance.json index b01d882dc..c11bc6117 100644 --- a/data_descriptors/standard_name/growth_limitation_of_diatoms_due_to_solar_irradiance.json +++ b/data_descriptors/standard_name/growth_limitation_of_diatoms_due_to_solar_irradiance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/growth_limitation_of_diatoms_due_to_solar_irradiance", + "id": "growth_limitation_of_diatoms_due_to_solar_irradiance", "type": "standard_name", "name": "growth_limitation_of_diatoms_due_to_solar_irradiance", "description": "Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy. Solar irradiance is essential to the photosynthesis reaction and its presence promotes the growth of phytoplankton populations. \"Growth limitation due to solar irradiance\" means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", diff --git a/data_descriptors/standard_name/growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance.json b/data_descriptors/standard_name/growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance.json index a47cf7441..8c473e884 100644 --- a/data_descriptors/standard_name/growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance.json +++ b/data_descriptors/standard_name/growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance", + "id": "growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance", "type": "standard_name", "name": "growth_limitation_of_diazotrophic_phytoplankton_due_to_solar_irradiance", "description": "\"Growth limitation due to solar irradiance\" means the ratio of the growth rate of a biological population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy. Solar irradiance is essential to the photosynthesis reaction and its presence promotes the growth of phytoplankton populations. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance.json b/data_descriptors/standard_name/growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance.json index 78f01c75e..db4561dfa 100644 --- a/data_descriptors/standard_name/growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance.json +++ b/data_descriptors/standard_name/growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance", + "id": "growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance", "type": "standard_name", "name": "growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance", "description": "Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy. Solar irradiance is essential to the photosynthesis reaction and its presence promotes the growth of phytoplankton populations. \"Growth limitation due to solar irradiance\" means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", diff --git a/data_descriptors/standard_name/growth_limitation_of_picophytoplankton_due_to_solar_irradiance.json b/data_descriptors/standard_name/growth_limitation_of_picophytoplankton_due_to_solar_irradiance.json index e632ff90b..4391dc147 100644 --- a/data_descriptors/standard_name/growth_limitation_of_picophytoplankton_due_to_solar_irradiance.json +++ b/data_descriptors/standard_name/growth_limitation_of_picophytoplankton_due_to_solar_irradiance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/growth_limitation_of_picophytoplankton_due_to_solar_irradiance", + "id": "growth_limitation_of_picophytoplankton_due_to_solar_irradiance", "type": "standard_name", "name": "growth_limitation_of_picophytoplankton_due_to_solar_irradiance", "description": "Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy. Solar irradiance is essential to the photosynthesis reaction and its presence promotes the growth of phytoplankton populations. \"Growth limitation due to solar irradiance\" means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", diff --git a/data_descriptors/standard_name/hail_fall_amount.json b/data_descriptors/standard_name/hail_fall_amount.json index f25da6d10..64e8ee5bb 100644 --- a/data_descriptors/standard_name/hail_fall_amount.json +++ b/data_descriptors/standard_name/hail_fall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/hail_fall_amount", + "id": "hail_fall_amount", "type": "standard_name", "name": "hail_fall_amount", "description": "\"Amount\" means mass per unit area. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. For diameters of less than 5 mm standard names for \"graupel\" should be used. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/hail_fall_flux.json b/data_descriptors/standard_name/hail_fall_flux.json index 30c6d0e70..43db60f4b 100644 --- a/data_descriptors/standard_name/hail_fall_flux.json +++ b/data_descriptors/standard_name/hail_fall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/hail_fall_flux", + "id": "hail_fall_flux", "type": "standard_name", "name": "hail_fall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. For diameters of less than 5 mm standard names for \"graupel\" should be used. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/halosteric_change_in_mean_sea_level.json b/data_descriptors/standard_name/halosteric_change_in_mean_sea_level.json index b8cf3f89a..fe0822a4c 100644 --- a/data_descriptors/standard_name/halosteric_change_in_mean_sea_level.json +++ b/data_descriptors/standard_name/halosteric_change_in_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/halosteric_change_in_mean_sea_level", + "id": "halosteric_change_in_mean_sea_level", "type": "standard_name", "name": "halosteric_change_in_mean_sea_level", "description": "Halosteric sea level change is the part caused by change in sea water density due to change in salinity. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. Zero mean sea level change is an arbitrary level. The sum of the quantities with standard names thermosteric_change_in_mean_sea_level and halosteric_change_in_mean_sea_level has the standard name steric_change_in_mean_sea_level.", diff --git a/data_descriptors/standard_name/halosteric_change_in_sea_surface_height.json b/data_descriptors/standard_name/halosteric_change_in_sea_surface_height.json index a4ad2676e..d407610c0 100644 --- a/data_descriptors/standard_name/halosteric_change_in_sea_surface_height.json +++ b/data_descriptors/standard_name/halosteric_change_in_sea_surface_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/halosteric_change_in_sea_surface_height", + "id": "halosteric_change_in_sea_surface_height", "type": "standard_name", "name": "halosteric_change_in_sea_surface_height", "description": "\"Sea surface height\" is a time-varying quantity. The halosteric change in sea surface height is the change in height that a water column of standard practical salinity S=35.0 would undergo when its salinity is changed to the observed value. The sum of the quantities with standard names thermosteric_change_in_sea_surface_height and halosteric_change_in_sea_surface_height is the total steric change in the water column height, which has the standard name of steric_change_in_sea_surface_height.", diff --git a/data_descriptors/standard_name/harmonic_period.json b/data_descriptors/standard_name/harmonic_period.json index 245dcd08f..fd066b8fe 100644 --- a/data_descriptors/standard_name/harmonic_period.json +++ b/data_descriptors/standard_name/harmonic_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/harmonic_period", + "id": "harmonic_period", "type": "standard_name", "name": "harmonic_period", "description": "A period is an interval of time, or the time-period of an oscillation.", diff --git a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_flux_adjustment.json b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_flux_adjustment.json index 9e6ff9b32..f29a9a963 100644 --- a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_flux_adjustment.json +++ b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_flux_adjustment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_flux_into_sea_water_due_to_flux_adjustment", + "id": "heat_flux_into_sea_water_due_to_flux_adjustment", "type": "standard_name", "name": "heat_flux_into_sea_water_due_to_flux_adjustment", "description": "A positive flux adjustment is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_freezing_of_frazil_ice.json b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_freezing_of_frazil_ice.json index 7eeee9488..3cbc59054 100644 --- a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_freezing_of_frazil_ice.json +++ b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_freezing_of_frazil_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_flux_into_sea_water_due_to_freezing_of_frazil_ice", + "id": "heat_flux_into_sea_water_due_to_freezing_of_frazil_ice", "type": "standard_name", "name": "heat_flux_into_sea_water_due_to_freezing_of_frazil_ice", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Frazil\" consists of needle like crystals of ice, typically between three and four millimeters in diameter, which form as sea water begins to freeze. Salt is expelled during the freezing process and frazil ice consists of nearly pure fresh water.", diff --git a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_iceberg_thermodynamics.json b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_iceberg_thermodynamics.json index 6a46c82c1..d171d257f 100644 --- a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_iceberg_thermodynamics.json +++ b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_iceberg_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_flux_into_sea_water_due_to_iceberg_thermodynamics", + "id": "heat_flux_into_sea_water_due_to_iceberg_thermodynamics", "type": "standard_name", "name": "heat_flux_into_sea_water_due_to_iceberg_thermodynamics", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \" Iceberg thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", diff --git a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_newtonian_relaxation.json b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_newtonian_relaxation.json index 0397f5b23..714212635 100644 --- a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_newtonian_relaxation.json +++ b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_newtonian_relaxation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_flux_into_sea_water_due_to_newtonian_relaxation", + "id": "heat_flux_into_sea_water_due_to_newtonian_relaxation", "type": "standard_name", "name": "heat_flux_into_sea_water_due_to_newtonian_relaxation", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The heat_flux_into_sea_water_due_to_newtonian_relaxation is the heat flux resulting from the Newtonian relaxation of the sea surface temperature. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_sea_ice_thermodynamics.json index 35d20892e..2e08e8385 100644 --- a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_flux_into_sea_water_due_to_sea_ice_thermodynamics", + "id": "heat_flux_into_sea_water_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "heat_flux_into_sea_water_due_to_sea_ice_thermodynamics", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_snow_thermodynamics.json b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_snow_thermodynamics.json index 187f86982..984ca2ea1 100644 --- a/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_snow_thermodynamics.json +++ b/data_descriptors/standard_name/heat_flux_into_sea_water_due_to_snow_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_flux_into_sea_water_due_to_snow_thermodynamics", + "id": "heat_flux_into_sea_water_due_to_snow_thermodynamics", "type": "standard_name", "name": "heat_flux_into_sea_water_due_to_snow_thermodynamics", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Snow thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", diff --git a/data_descriptors/standard_name/heat_index_of_air_temperature.json b/data_descriptors/standard_name/heat_index_of_air_temperature.json index 54c15ebf2..2b9973774 100644 --- a/data_descriptors/standard_name/heat_index_of_air_temperature.json +++ b/data_descriptors/standard_name/heat_index_of_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/heat_index_of_air_temperature", + "id": "heat_index_of_air_temperature", "type": "standard_name", "name": "heat_index_of_air_temperature", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The quantity with standard name heat_index_of_air_temperature is the perceived air temperature when relative humidity is taken into consideration (which makes it feel hotter than the actual air temperature). Heat index is only defined when the ambient air temperature is at or above 299.817 K. References: https://www.weather.gov/safety/heat-index; WMO codes registry entry http://codes.wmo.int/grib2/codeflag/4.2/_0-0-12. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/height.json b/data_descriptors/standard_name/height.json index c1ceaa8d9..952c37f8e 100644 --- a/data_descriptors/standard_name/height.json +++ b/data_descriptors/standard_name/height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height", + "id": "height", "type": "standard_name", "name": "height", "description": "Height is the vertical distance above the surface.", diff --git a/data_descriptors/standard_name/height_above_geopotential_datum.json b/data_descriptors/standard_name/height_above_geopotential_datum.json index b742bf959..bfbc78825 100644 --- a/data_descriptors/standard_name/height_above_geopotential_datum.json +++ b/data_descriptors/standard_name/height_above_geopotential_datum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_above_geopotential_datum", + "id": "height_above_geopotential_datum", "type": "standard_name", "name": "height_above_geopotential_datum", "description": "\"Height_above_X\" means the vertical distance above the named surface X. The \"geopotential datum\" is any estimated surface of constant geopotential used as a datum i.e. a reference level; for the geoid as a datum, specific standard names are available. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/height_above_geopotential_datum_at_top_of_atmosphere_model.json b/data_descriptors/standard_name/height_above_geopotential_datum_at_top_of_atmosphere_model.json index 722f2980e..6b10faa15 100644 --- a/data_descriptors/standard_name/height_above_geopotential_datum_at_top_of_atmosphere_model.json +++ b/data_descriptors/standard_name/height_above_geopotential_datum_at_top_of_atmosphere_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_above_geopotential_datum_at_top_of_atmosphere_model", + "id": "height_above_geopotential_datum_at_top_of_atmosphere_model", "type": "standard_name", "name": "height_above_geopotential_datum_at_top_of_atmosphere_model", "description": "\"Height_above_X\" means the vertical distance above the named surface X. The \"geopotential datum\" is any estimated surface of constant geopotential used as a datum i.e. a reference level; for the geoid as a datum, specific standard names are available. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention. \"Top of atmosphere model\" means the upper boundary of the top layer of an atmosphere model.", diff --git a/data_descriptors/standard_name/height_above_mean_sea_level.json b/data_descriptors/standard_name/height_above_mean_sea_level.json index 34dccac07..c5c27c812 100644 --- a/data_descriptors/standard_name/height_above_mean_sea_level.json +++ b/data_descriptors/standard_name/height_above_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_above_mean_sea_level", + "id": "height_above_mean_sea_level", "type": "standard_name", "name": "height_above_mean_sea_level", "description": "\"Height_above_X\" means the vertical distance above the named surface X. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals.", diff --git a/data_descriptors/standard_name/height_above_reference_ellipsoid.json b/data_descriptors/standard_name/height_above_reference_ellipsoid.json index 8a2d16fa7..4431b2bd5 100644 --- a/data_descriptors/standard_name/height_above_reference_ellipsoid.json +++ b/data_descriptors/standard_name/height_above_reference_ellipsoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_above_reference_ellipsoid", + "id": "height_above_reference_ellipsoid", "type": "standard_name", "name": "height_above_reference_ellipsoid", "description": "\"Height_above_X\" means the vertical distance above the named surface X. A reference ellipsoid is a mathematical figure that approximates the geoid. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. The ellipsoid is an approximation because the geoid is an irregular shape. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/height_above_sea_floor.json b/data_descriptors/standard_name/height_above_sea_floor.json index 826b78201..4b7f91199 100644 --- a/data_descriptors/standard_name/height_above_sea_floor.json +++ b/data_descriptors/standard_name/height_above_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_above_sea_floor", + "id": "height_above_sea_floor", "type": "standard_name", "name": "height_above_sea_floor", "description": null, diff --git a/data_descriptors/standard_name/height_at_cloud_top.json b/data_descriptors/standard_name/height_at_cloud_top.json index 1b2920f24..9eb1fede6 100644 --- a/data_descriptors/standard_name/height_at_cloud_top.json +++ b/data_descriptors/standard_name/height_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_at_cloud_top", + "id": "height_at_cloud_top", "type": "standard_name", "name": "height_at_cloud_top", "description": "cloud_top refers to the top of the highest cloud. Height is the vertical distance above the surface.", diff --git a/data_descriptors/standard_name/height_at_effective_cloud_top_defined_by_infrared_radiation.json b/data_descriptors/standard_name/height_at_effective_cloud_top_defined_by_infrared_radiation.json index 0ac6db02c..bf4f616de 100644 --- a/data_descriptors/standard_name/height_at_effective_cloud_top_defined_by_infrared_radiation.json +++ b/data_descriptors/standard_name/height_at_effective_cloud_top_defined_by_infrared_radiation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/height_at_effective_cloud_top_defined_by_infrared_radiation", + "id": "height_at_effective_cloud_top_defined_by_infrared_radiation", "type": "standard_name", "name": "height_at_effective_cloud_top_defined_by_infrared_radiation", "description": "The \"effective cloud top defined by infrared radiation\" is (approximately) the geometric height above the surface that is one optical depth at infrared wavelengths (in the region of 11 micrometers) below the cloud top that would be detected by visible and lidar techniques. Reference: Minnis, P. et al 2011 CERES Edition-2 Cloud Property Retrievals Using TRMM VIRS and Terra and Aqua MODIS Data x2014; Part I: Algorithms IEEE Transactions on Geoscience and Remote Sensing, 49(11), 4374-4400. doi: http://dx.doi.org/10.1109/TGRS.2011.2144601.", diff --git a/data_descriptors/standard_name/high_type_cloud_area_fraction.json b/data_descriptors/standard_name/high_type_cloud_area_fraction.json index dfa6d25c7..d1db21138 100644 --- a/data_descriptors/standard_name/high_type_cloud_area_fraction.json +++ b/data_descriptors/standard_name/high_type_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/high_type_cloud_area_fraction", + "id": "high_type_cloud_area_fraction", "type": "standard_name", "name": "high_type_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. High type clouds are: Cirrus, Cirrostratus, Cirrocumulus. X_type_cloud_area_fraction is generally determined on the basis of cloud type, though Numerical Weather Prediction (NWP) models often calculate them based on the vertical location of the cloud. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid.json b/data_descriptors/standard_name/histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid.json index f3c43fc88..9e99eebfb 100644 --- a/data_descriptors/standard_name/histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid.json +++ b/data_descriptors/standard_name/histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid", + "id": "histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid", "type": "standard_name", "name": "histogram_of_backscattering_ratio_in_air_over_height_above_reference_ellipsoid", "description": "Scattering of radiation is its deflection from its incident path without loss of energy. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity. \"Backscattering ratio\" is the ratio of the quantity with standard name volume_attenuated_backwards_scattering_function_in_air to the quantity with standard name volume_attenuated_backwards_scattering_function_in_air_assuming_no_aerosol_or_cloud. \"histogram_of_X[_over_Z]\" means histogram (i.e. number of counts for each range of X) of variations (over Z) of X. The data variable should have an axis for X. A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid.json b/data_descriptors/standard_name/histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid.json index 3b33f9f3f..c5d3b08f6 100644 --- a/data_descriptors/standard_name/histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid.json +++ b/data_descriptors/standard_name/histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid", + "id": "histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid", "type": "standard_name", "name": "histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid", "description": "\"Equivalent reflectivity factor\" is the radar reflectivity factor that is calculated from the measured radar return power assuming the target is composed of liquid water droplets whose diameter is less than one tenth of the radar wavelength, i.e., treating the droplets as Rayleigh scatterers. The actual radar reflectivity factor would depend on the size distribution and composition of the particles within the target volume and these are often unknown. \"histogram_of_X[_over_Z]\" means histogram (i.e. number of counts for each range of X) of variations (over Z) of X. The data variable should have an axis for X. A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/horizontal_atmosphere_dry_energy_transport.json b/data_descriptors/standard_name/horizontal_atmosphere_dry_energy_transport.json index 5f1265f27..6d723563d 100644 --- a/data_descriptors/standard_name/horizontal_atmosphere_dry_energy_transport.json +++ b/data_descriptors/standard_name/horizontal_atmosphere_dry_energy_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/horizontal_atmosphere_dry_energy_transport", + "id": "horizontal_atmosphere_dry_energy_transport", "type": "standard_name", "name": "horizontal_atmosphere_dry_energy_transport", "description": "Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/horizontal_dry_energy_transport_in_atmosphere_layer.json b/data_descriptors/standard_name/horizontal_dry_energy_transport_in_atmosphere_layer.json index 2c6528a62..a44539a2d 100644 --- a/data_descriptors/standard_name/horizontal_dry_energy_transport_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/horizontal_dry_energy_transport_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/horizontal_dry_energy_transport_in_atmosphere_layer", + "id": "horizontal_dry_energy_transport_in_atmosphere_layer", "type": "standard_name", "name": "horizontal_dry_energy_transport_in_atmosphere_layer", "description": "\"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/humidity_mixing_ratio.json b/data_descriptors/standard_name/humidity_mixing_ratio.json index 922320d03..daf859997 100644 --- a/data_descriptors/standard_name/humidity_mixing_ratio.json +++ b/data_descriptors/standard_name/humidity_mixing_ratio.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/humidity_mixing_ratio", + "id": "humidity_mixing_ratio", "type": "standard_name", "name": "humidity_mixing_ratio", "description": "Humidity mixing ratio of a parcel of moist air is the ratio of the mass of water vapor to the mass of dry air.", diff --git a/data_descriptors/standard_name/ice_cloud_area_fraction.json b/data_descriptors/standard_name/ice_cloud_area_fraction.json index 6eff2593a..e5bebcda6 100644 --- a/data_descriptors/standard_name/ice_cloud_area_fraction.json +++ b/data_descriptors/standard_name/ice_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ice_cloud_area_fraction", + "id": "ice_cloud_area_fraction", "type": "standard_name", "name": "ice_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names also exist for high, medium and low cloud types. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/ice_cloud_area_fraction_in_atmosphere_layer.json b/data_descriptors/standard_name/ice_cloud_area_fraction_in_atmosphere_layer.json index 7ad82275b..6b6101768 100644 --- a/data_descriptors/standard_name/ice_cloud_area_fraction_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/ice_cloud_area_fraction_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ice_cloud_area_fraction_in_atmosphere_layer", + "id": "ice_cloud_area_fraction_in_atmosphere_layer", "type": "standard_name", "name": "ice_cloud_area_fraction_in_atmosphere_layer", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Standard names also exist for high, medium and low cloud types. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume.json b/data_descriptors/standard_name/ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume.json index 9b4164b64..5bd706628 100644 --- a/data_descriptors/standard_name/ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume.json +++ b/data_descriptors/standard_name/ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume", + "id": "ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume", "type": "standard_name", "name": "ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume", "description": "ice_volume_in_frozen_ground_in_excess_of_pore_volume_in_unfrozen_ground_expressed_as_fraction_of_frozen_ground_volume represents the fractional amount of \"excess ice\" in frozen ground. Excess ice is the volume of ice in the ground which exceeds the total pore volume that the ground would have under natural unfrozen conditions. Due to the presence of ground ice, the total water content of a frozen soil may exceed that corresponding to its normally consolidated state when unfrozen. As a result, upon thawing, a soil containing excess ice will settle under its own weight until it attains its consolidated state. Reference: van Everdingen, R. O. editor 1998: Multi-language glossary of permafrost and related ground ice terms. International Permafrost Association.", diff --git a/data_descriptors/standard_name/incoming_water_volume_transport_along_river_channel.json b/data_descriptors/standard_name/incoming_water_volume_transport_along_river_channel.json index 20c185271..2f60dcfac 100644 --- a/data_descriptors/standard_name/incoming_water_volume_transport_along_river_channel.json +++ b/data_descriptors/standard_name/incoming_water_volume_transport_along_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/incoming_water_volume_transport_along_river_channel", + "id": "incoming_water_volume_transport_along_river_channel", "type": "standard_name", "name": "incoming_water_volume_transport_along_river_channel", "description": "\"Water\" means water in all phases. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json b/data_descriptors/standard_name/indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json index fc966aea1..746c7f80e 100644 --- a/data_descriptors/standard_name/indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json +++ b/data_descriptors/standard_name/indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water", + "id": "indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water", "type": "standard_name", "name": "indicative_error_from_multibeam_acoustic_doppler_velocity_profiler_in_sea_water", "description": "Sea water velocity is a vector quantity that is the speed at which water travels in a specified direction. The \"indicative error\" is an estimate of the quality of a sea water velocity profile measured using an ADCP (acoustic doppler current profiler). It is determined by the difference between the vertical velocity calculated from two 3-beam solutions. The parameter is frequently referred to as the \"error velocity\".", diff --git a/data_descriptors/standard_name/institution.json b/data_descriptors/standard_name/institution.json index cc201566d..03bdd7468 100644 --- a/data_descriptors/standard_name/institution.json +++ b/data_descriptors/standard_name/institution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/institution", + "id": "institution", "type": "standard_name", "name": "institution", "description": "An auxiliary coordinate variable with a standard name of institution contains string values which specify where the original data, with which the coordinate variable is associated, were produced. The use of institution as the standard name for an auxiliary coordinate variable permits the aggregation of data from multiple institutions within a single data file.", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density.json b/data_descriptors/standard_name/integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density.json index 12bb5ba96..a2797b99e 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density", + "id": "integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density", "type": "standard_name", "name": "integral_wrt_depth_of_product_of_conservative_temperature_and_sea_water_density", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. The phrase \"wrt\" means \"with respect to\". Depth is the vertical distance below the surface. The phrase \"product_of_X_and_Y\" means X*Y. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. Sea water density is the in-situ density (not the potential density). For Boussinesq models, density is the constant Boussinesq reference density, a quantity which has the standard name reference_sea_water_density_for_boussinesq_approximation. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density.json b/data_descriptors/standard_name/integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density.json index 9f723075f..453da5caa 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density", + "id": "integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density", "type": "standard_name", "name": "integral_wrt_depth_of_product_of_potential_temperature_and_sea_water_density", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. The phrase \"wrt\" means \"with respect to\". The phrase \"product_of_X_and_Y\" means X*Y. Depth is the vertical distance below the surface. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. Sea water density is the in-situ density (not the potential density). For Boussinesq models, density is the constant Boussinesq reference density, a quantity which has the standard name reference_sea_water_density_for_boussinesq_approximation. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_product_of_salinity_and_sea_water_density.json b/data_descriptors/standard_name/integral_wrt_depth_of_product_of_salinity_and_sea_water_density.json index 4284e5d90..6b4c45870 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_product_of_salinity_and_sea_water_density.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_product_of_salinity_and_sea_water_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_product_of_salinity_and_sea_water_density", + "id": "integral_wrt_depth_of_product_of_salinity_and_sea_water_density", "type": "standard_name", "name": "integral_wrt_depth_of_product_of_salinity_and_sea_water_density", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. The phrase \"wrt\" means \"with respect to\". The phrase \"product_of_X_and_Y\" means X*Y. Depth is the vertical distance below the surface. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. Practical salinity units are dimensionless. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity. Sea water density is the in-situ density (not the potential density). For Boussinesq models, density is the constant Boussinesq reference density, a quantity which has the standard name reference_sea_water_density_for_boussinesq_approximation.", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_practical_salinity.json b/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_practical_salinity.json index 01f4c2038..f5c462d4f 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_practical_salinity.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_practical_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_sea_water_practical_salinity", + "id": "integral_wrt_depth_of_sea_water_practical_salinity", "type": "standard_name", "name": "integral_wrt_depth_of_sea_water_practical_salinity", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. \"wrt\" means with respect to. Depth is the vertical distance below the surface. Practical Salinity, S_P, is a determination of the salinity of sea water, based on its electrical conductance. The measured conductance, corrected for temperature and pressure, is compared to the conductance of a standard potassium chloride solution, producing a value on the Practical Salinity Scale of 1978 (PSS-78). This name should not be used to describe salinity observations made before 1978, or ones not based on conductance measurements. Conversion of Practical Salinity to other precisely defined salinity measures should use the appropriate formulas specified by TEOS-10. Other standard names for precisely defined salinity quantities are sea_water_absolute_salinity (S_A); sea_water_preformed_salinity (S_*), sea_water_reference_salinity (S_R); sea_water_cox_salinity (S_C), used for salinity observations between 1967 and 1977; and sea_water_knudsen_salinity (S_K), used for salinity observations between 1901 and 1966. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity. Reference: www.teos-10.org; Lewis, 1980 doi:10.1109/JOE.1980.1145448.", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_temperature.json b/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_temperature.json index 88b14855a..c00b05445 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_temperature.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_sea_water_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_sea_water_temperature", + "id": "integral_wrt_depth_of_sea_water_temperature", "type": "standard_name", "name": "integral_wrt_depth_of_sea_water_temperature", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. \"wrt\" means with respect to. Depth is the vertical distance below the surface. Sea water temperature is the in situ temperature of the sea water. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent.json b/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent.json index 0b95ed80c..601e636f6 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent", + "id": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent", "type": "standard_name", "name": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. \"wrt\" means with respect to. Depth is the vertical distance below the surface.\"tendency_of_X\" means derivative of X with respect to time. 'sea_water_alkalinity_expressed_as_mole_equivalent' is the total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components).", diff --git a/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json b/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json index 0ff7c2fc2..85e404167 100644 --- a/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json +++ b/data_descriptors/standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", + "id": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", "type": "standard_name", "name": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. \"wrt\" means with respect to. \"tendency_of_X\" means derivative of X with respect to time. Depth is the vertical distance below the surface. 'sea_water_alkalinity_expressed_as_mole_equivalent' is the total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air.json b/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air.json index fc72a1afd..c5e7d24b7 100644 --- a/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air", + "id": "integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air", "type": "standard_name", "name": "integral_wrt_height_of_product_of_eastward_wind_and_mass_concentration_of_water_vapor_in_air", "description": "Eastward vertically-integrated moisture flux per unit length in latitude. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Height is the vertical distance above the surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The phrase \"product_of_X_and_Y\" means X*Y. The abbreviation \"wrt\" means \"with respect to\". The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. \"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity.json b/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity.json index 6dfa40c73..289221392 100644 --- a/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity.json +++ b/data_descriptors/standard_name/integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity", + "id": "integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity", "type": "standard_name", "name": "integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. The phrase \"wrt\" means \"with respect to\". Height is the vertical distance above the surface. The phrase \"product_of_X_and_Y\" means X*Y. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\".) \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air.json b/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air.json index 023f83123..5f9a0802d 100644 --- a/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air", + "id": "integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air", "type": "standard_name", "name": "integral_wrt_height_of_product_of_northward_wind_and_mass_concentration_of_water_vapor_in_air", "description": "Northward vertically-integrated moisture flux per unit length in longitude. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Height is the vertical distance above the surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The phrase \"product_of_X_and_Y\" means X*Y. The abbreviation \"wrt\" means \"with respect to\". The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. \"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_specific_humidity.json b/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_specific_humidity.json index 54822afbf..7999f8b53 100644 --- a/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_specific_humidity.json +++ b/data_descriptors/standard_name/integral_wrt_height_of_product_of_northward_wind_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_height_of_product_of_northward_wind_and_specific_humidity", + "id": "integral_wrt_height_of_product_of_northward_wind_and_specific_humidity", "type": "standard_name", "name": "integral_wrt_height_of_product_of_northward_wind_and_specific_humidity", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. To specify the limits of the integral the data variable should have an axis for X and associated coordinate bounds. If no axis for X is associated with the data variable, or no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is air the integral is assumed to be calculated over the full depth of the atmosphere. The phrase \"wrt\" means \"with respect to\". Height is the vertical distance above the surface. The phrase \"product_of_X_and_Y\" means X*Y. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\".) \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_deficit.json b/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_deficit.json index c036bd9bc..c5da06e2a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_deficit.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_deficit.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_air_temperature_deficit", + "id": "integral_wrt_time_of_air_temperature_deficit", "type": "standard_name", "name": "integral_wrt_time_of_air_temperature_deficit", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The air temperature deficit is the air temperature threshold minus the air temperature, where only positive values are included in the integral. Its integral with respect to time is often called after its units of \"degree-days\". The air_temperature variable, which is the data variable of the integral should have a scalar coordinate variable or a size-one coordinate variable with the standard name of air_temperature_threshold, to indicate the threshold. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_excess.json b/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_excess.json index 5c77ea1ac..5f5d0888e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_excess.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_air_temperature_excess.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_air_temperature_excess", + "id": "integral_wrt_time_of_air_temperature_excess", "type": "standard_name", "name": "integral_wrt_time_of_air_temperature_excess", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The air temperature excess is the air temperature minus the air temperature threshold, where only positive values are included in the integral. Its integral with respect to time is often called after its units of \"degree-days\". The air_temperature variable, which is the data variable of the integral should have a scalar coordinate variable or a size-one coordinate variable with the standard name of air_temperature_threshold, to indicate the threshold. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_mole_stomatal_uptake_of_ozone.json b/data_descriptors/standard_name/integral_wrt_time_of_mole_stomatal_uptake_of_ozone.json index 004f65870..3152ee1dc 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_mole_stomatal_uptake_of_ozone.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_mole_stomatal_uptake_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_mole_stomatal_uptake_of_ozone", + "id": "integral_wrt_time_of_mole_stomatal_uptake_of_ozone", "type": "standard_name", "name": "integral_wrt_time_of_mole_stomatal_uptake_of_ozone", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". The stomatal ozone uptake is the net amount of ozone transferred into the plant during the time period over which the integral is calculated. This parameter is often called the \"phytotoxic ozone dose (POD)\". The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_in_air.json index 67dc69b62..84a8a2ba5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air.json index 90ffaecb6..adbedf7bd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_101Mo_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mo\" means the element \"molybdenum\" and \"101Mo\" is the isotope \"molybdenum-101\" with a half-life of 1.01e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air.json index dc7455454..c8ac95e77 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_101Tc_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"101Tc\" is the isotope \"technetium-101\" with a half-life of 9.86e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air.json index 9890400e9..39e1998ff 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_102Mo_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mo\" means the element \"molybdenum\" and \"102Mo\" is the isotope \"molybdenum-102\" with a half-life of 7.71e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air.json index 81c44ffba..c052219cc 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_102Tc_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"102Tc\" is the isotope \"technetium-102\" with a half-life of 6.12e-05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air.json index 33ac960cd..54ee6fc55 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_102mTc_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"102mTc\" is the metastable state of the isotope \"technetium-102\" with a half-life of 2.98e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air.json index be123758d..d80187546 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_103Ru_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ru\" means the element \"ruthenium\" and \"103Ru\" is the isotope \"ruthenium-103\" with a half-life of 3.95e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air.json index 56153ee6f..1ba04afde 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_103mRh_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"103mRh\" is the metastable state of the isotope \"rhodium-103\" with a half-life of 3.89e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air.json index 9855e8ceb..835264015 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_104Tc_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"104Tc\" is the isotope \"technetium-104\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air.json index edddff983..db912d70c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_105Rh_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"105Rh\" is the isotope \"rhodium-105\" with a half-life of 1.48e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air.json index fbaff793e..0adaab903 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_105Ru_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ru\" means the element \"ruthenium\" and \"105Ru\" is the isotope \"ruthenium-105\" with a half-life of 1.85e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air.json index 331cef50f..398443f43 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_105mRh_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"105mRh\" is the metastable state of the isotope \"rhodium-105\" with a half-life of 4.41e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air.json index 121edfde3..3f6b25e52 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_106Rh_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"106Rh\" is the isotope \"rhodium-106\" with a half-life of 3.46e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air.json index d1ccde0fa..2b0ca72f7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_106Ru_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ru\" means the element \"ruthenium\" and \"106Ru\" is the isotope \"ruthenium-106\" with a half-life of 3.66e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air.json index 4acddcabe..569940b7e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_106mRh_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"106mRh\" is the metastable state of the isotope \"rhodium-106\" with a half-life of 9.09e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air.json index 8ae4b3a11..7c8c6a7d6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_107Pd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"107Pd\" is the isotope \"palladium-107\" with a half-life of 2.37e+09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air.json index 03a9eba07..8280f0611 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_107Rh_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"107Rh\" is the isotope \"rhodium-107\" with a half-life of 1.51e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air.json index 4295e03b6..dfe96dd98 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_107mPd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"107mPd\" is the metastable state of the isotope \"palladium-107\" with a half-life of 2.47e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air.json index 09bec83cd..31e65c19e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_109Pd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"109Pd\" is the isotope \"palladium-109\" with a half-life of 5.61e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air.json index 892282996..efe97a056 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_109mAg_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"109mAg\" is the metastable state of the isotope \"silver-109\" with a half-life of 4.58e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air.json index c3f331d30..307bf21cd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_110mAg_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"110mAg\" is the metastable state of the isotope \"silver-110\" with a half-life of 2.70e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air.json index b17dd25fe..aa12ac56a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_111Ag_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"111Ag\" is the isotope \"silver-111\" with a half-life of 7.50e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air.json index 7f7660614..aa6d6d491 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_111Pd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"111Pd\" is the isotope \"palladium-111\" with a half-life of 1.53e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air.json index 14dc9f551..fa3b526e1 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_111mAg_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"111mAg\" is the metastable state of the isotope \"silver-111\" with a half-life of 8.56e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air.json index ccab69620..2f14fd9fa 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_111mCd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"111mCd\" is the metastable state of the isotope \"cadmium-111\" with a half-life of 3.39e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air.json index d064e4a4f..e246f1174 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_111mPd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"111mPd\" is the metastable state of the isotope \"palladium-111\" with a half-life of 2.29e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air.json index 1b8be201b..f1816f747 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_112Ag_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"112Ag\" is the isotope \"silver-112\" with a half-life of 1.30e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air.json index b65712c88..278c15285 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_112Pd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"112Pd\" is the isotope \"palladium-112\" with a half-life of 8.37e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air.json index 6e5770f8f..41dc1ab31 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_113Ag_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"113Ag\" is the isotope \"silver-113\" with a half-life of 2.21e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air.json index 50a61a35e..5384db5bd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_113Cd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"113Cd\" is the isotope \"cadmium-113\" with a half-life of 3.29e+18 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air.json index c3ef3324c..26cd47cfa 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_113mAg_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"113mAg\" is the metastable state of the isotope \"silver-113\" with a half-life of 7.64e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air.json index caa19b830..c445ab79a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_113mCd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"113mCd\" is the metastable state of the isotope \"cadmium-113\" with a half-life of 5.31e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air.json index 7ff612cd9..c6c1c70d7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_113mIn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"113mIn\" is the metastable state of the isotope \"indium-113\" with a half-life of 6.92e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air.json index 3076c2a54..c01aa7f2f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_115Ag_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"115Ag\" is the isotope \"silver-115\" with a half-life of 1.46e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air.json index 7c1dcea55..9c787d91b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_115Cd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"115Cd\" is the isotope \"cadmium-115\" with a half-life of 2.23e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115In_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115In_in_air.json index 6b61fbdb9..d370e461f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115In_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_115In_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_115In_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_115In_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"115In\" is the isotope \"indium-115\" with a half-life of 1.86e+18 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air.json index 72916ab8e..a5c3ae5f6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_115mAg_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"115mAg\" is the metastable state of the isotope \"silver-115\" with a half-life of 1.97e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air.json index 69ca0e3a6..0abe613ae 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_115mCd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"115mCd\" is the metastable state of the isotope \"cadmium-115\" with a half-life of 4.46e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air.json index c4d04723a..c2d3d72c1 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_115mIn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"115mIn\" is the metastable state of the isotope \"indium-115\" with a half-life of 1.87e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116In_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116In_in_air.json index 82b5dfdb1..4be24d1b0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116In_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_116In_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_116In_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_116In_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"116In\" is the isotope \"indium-116\" with a half-life of 1.64e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air.json index 058a17963..d9b094aa9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_116mIn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"116mIn\" is the metastable state of the isotope \"indium-116\" with a half-life of 3.77e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air.json index c66b1007f..1ba22f925 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_117Cd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"117Cd\" is the isotope \"cadmium-117\" with a half-life of 1.08e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117In_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117In_in_air.json index 03e7b0249..5f0d2c572 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117In_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_117In_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_117In_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_117In_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"117In\" is the isotope \"indium-117\" with a half-life of 3.05e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air.json index 56ee5fae9..3017ee6df 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_117mCd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"117mCd\" is the metastable state of the isotope \"cadmium-117\" with a half-life of 1.42e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air.json index f761d71f0..ff9b9b338 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_117mIn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"117mIn\" is the metastable state of the isotope \"indium-117\" with a half-life of 8.08e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air.json index 5c742c78c..299467861 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_117mSn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"117mSn\" is the metastable state of the isotope \"tin-117\" with a half-life of 1.40e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air.json index 35fdbb65a..88f901b57 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_118Cd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"118Cd\" is the isotope \"cadmium-118\" with a half-life of 3.49e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118In_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118In_in_air.json index 7b531d934..877544e32 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118In_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_118In_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_118In_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_118In_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"118In\" is the isotope \"indium-118\" with a half-life of 5.77e-05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air.json index 17b3f5388..ed73d2f11 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_118mIn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"118mIn\" is the metastable state of the isotope \"indium-118\" with a half-life of 3.05e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119In_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119In_in_air.json index 6d69d778f..360d62725 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119In_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_119In_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_119In_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_119In_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"119In\" is the isotope \"indium-119\" with a half-life of 1.74e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air.json index bdce8177e..00b7f19db 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_119mIn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"119mIn\" is the metastable state of the isotope \"indium-119\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air.json index 6ddd0ea93..60fc91e15 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_119mSn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"119mSn\" is the metastable state of the isotope \"tin-119\" with a half-life of 2.45e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_11C_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_11C_in_air.json index 639ff8b62..a26dbc32f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_11C_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_11C_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_11C_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_11C_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_11C_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"C\" means the element \"carbon\" and \"11C\" is the isotope \"carbon-11\" with a half-life of 1.41e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air.json index d0f6f3d19..7f5759021 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_121Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"121Sn\" is the isotope \"tin-121\" with a half-life of 1.12e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air.json index 38298b4d5..02a1cfd4f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_121mSn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"121mSn\" is the metastable state of the isotope \"tin-121\" with a half-life of 1.82e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air.json index 65dfe063b..67a7a3200 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_123Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"123Sn\" is the isotope \"tin-123\" with a half-life of 1.29e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air.json index 0c61b01aa..1296aff1a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_123mSn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"123mSn\" is the metastable state of the isotope \"tin-123\" with a half-life of 2.78e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air.json index 29a3acc28..95c3bbfdd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_124Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"124Sb\" is the isotope \"antimony-124\" with a half-life of 6.03e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air.json index 2f316bf97..b35d2f77e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_124mSb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"124mSb\" is the metastable state of the isotope \"antimony-124\" with a half-life of 1.41e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air.json index d83103002..052f285af 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_125Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"125Sb\" is the isotope \"antimony-125\" with a half-life of 9.97e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air.json index 6f42efa76..059333876 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_125Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"125Sn\" is the isotope \"tin-125\" with a half-life of 9.65e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air.json index ec7157c7e..c9a197222 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_125mTe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"125mTe\" is the metastable state of the isotope \"tellurium-125\" with a half-life of 5.81e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air.json index ec0c704c5..b608014f3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_126Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"126Sb\" is the isotope \"antimony-126\" with a half-life of 1.24e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air.json index 956fb87df..32d3aef03 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_126Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"126Sn\" is the isotope \"tin-126\" with a half-life of 3.65e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air.json index f5a253156..e6786bdf9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_126mSb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"126mSb\" is the metastable state of the isotope \"antimony-126\" with a half-life of 1.32e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air.json index c1d316dc9..0ed16a59e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_127Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"127Sb\" is the isotope \"antimony-127\" with a half-life of 3.80e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air.json index 032f4781a..e83e30b33 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_127Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"127Sn\" is the isotope \"tin-127\" with a half-life of 8.84e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air.json index e8c53fe2f..7cd14b8ea 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_127Te_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"127Te\" is the isotope \"tellurium-127\" with a half-life of 3.91e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air.json index 4b6dcd08e..d052e50a6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_127mTe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"127mTe\" is the metastable state of the isotope \"tellurium-127\" with a half-life of 1.09e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air.json index d33a1421b..d159e4e95 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_128Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"128Sb\" is the isotope \"antimony-128\" with a half-life of 3.75e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air.json index 2265c660e..63c6ac1ef 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_128Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"128Sn\" is the isotope \"tin-128\" with a half-life of 4.09e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air.json index aa8dc9098..691e9b1fc 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_128mSb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"128mSb\" is the metastable state of the isotope \"antimony-128\" with a half-life of 7.23e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129I_in_air.json index f595fd5d5..75b7dc48c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_129I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_129I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_129I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"129I\" is the isotope \"iodine-129\" with a half-life of 5.81e+09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air.json index 20b29c19a..7d276642f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_129Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"129Sb\" is the isotope \"antimony-129\" with a half-life of 1.81e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air.json index 20d75e7c2..72661733b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_129Te_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"129Te\" is the isotope \"tellurium-129\" with a half-life of 4.86e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air.json index c62807942..70392ef4d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_129mTe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"129mTe\" is the metastable state of the isotope \"tellurium-129\" with a half-life of 3.34e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air.json index 9845e9b7f..e1797e8a3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_129mXe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"129mXe\" is the metastable state of the isotope \"xenon-129\" with a half-life of 8.02e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130I_in_air.json index e84125a11..f1e008ccf 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_130I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_130I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_130I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"130I\" is the isotope \"iodine-130\" with a half-life of 5.18e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air.json index daf110a3a..83b6fd0f8 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_130Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"130Sb\" is the isotope \"antimony-130\" with a half-life of 2.57e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air.json index e21306725..b92497427 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_130Sn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"130Sn\" is the isotope \"tin-130\" with a half-life of 2.57e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air.json index 39a1d7a3d..5f5e5588a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_130mI_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"130mI\" is the metastable state of the isotope \"iodine-130\" with a half-life of 6.17e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air.json index a595ebb93..e05dd6cc0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_130mSb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"130mSb\" is the metastable state of the isotope \"antimony-130\" with a half-life of 4.58e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131I_in_air.json index 1128cf5cb..5e9f7354b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_131I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_131I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_131I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"131I\" is the isotope \"iodine-131\" with a half-life of 8.07e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air.json index 4ac652041..0776e75b3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_131Sb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"131Sb\" is the isotope \"antimony-131\" with a half-life of 1.60e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air.json index 8ee513aa1..0c70a8c0b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_131Te_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"131Te\" is the isotope \"tellurium-131\" with a half-life of 1.74e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air.json index bd89b4a86..ccd9eaa4b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_131mTe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"131mTe\" is the metastable state of the isotope \"tellurium-131\" with a half-life of 1.25e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air.json index a048189d7..485a1c142 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_131mXe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"131mXe\" is the metastable state of the isotope \"xenon-131\" with a half-life of 1.18e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132I_in_air.json index d9a808bba..cca82edca 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_132I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_132I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_132I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"132I\" is the isotope \"iodine-132\" with a half-life of 9.60e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air.json index 3e6b2d088..981773b87 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_132Te_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"132Te\" is the isotope \"tellurium-132\" with a half-life of 3.25e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133I_in_air.json index c14de95cf..af79e5fbe 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_133I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_133I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_133I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"133I\" is the isotope \"iodine-133\" with a half-life of 8.71e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air.json index 873616ea4..900da3c23 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_133Te_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"133Te\" is the isotope \"tellurium-133\" with a half-life of 8.68e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air.json index 5f9c97680..b7147f1e7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_133Xe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"133Xe\" is the isotope \"xenon-133\" with a half-life of 5.28e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air.json index b44c6f974..29fc416a4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_133mI_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"133mI\" is the metastable state of the isotope \"iodine-133\" with a half-life of 1.04e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air.json index 8d4b3cac9..da9880b54 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_133mTe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"133mTe\" is the metastable state of the isotope \"tellurium-133\" with a half-life of 3.84e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air.json index 100660820..d0b1c6e30 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_133mXe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"133mXe\" is the metastable state of the isotope \"xenon-133\" with a half-life of 2.26e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air.json index f489a3d6f..27173b3b4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_134Cs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"134Cs\" is the isotope \"cesium-134\" with a half-life of 7.50e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134I_in_air.json index 54f2337b0..2bb3faaaa 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_134I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_134I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_134I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"134I\" is the isotope \"iodine-134\" with a half-life of 3.61e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air.json index d0c4042ba..58f875b92 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_134Te_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"134Te\" is the isotope \"tellurium-134\" with a half-life of 2.92e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air.json index ae037f2b2..227a50199 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_134mCs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"134mCs\" is the metastable state of the isotope \"cesium-134\" with a half-life of 1.21e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air.json index a2d266b9b..f6f7cb82a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_134mI_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"134mI\" is the metastable state of the isotope \"iodine-134\" with a half-life of 2.50e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air.json index 25ff4d514..feb36283f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_134mXe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"134mXe\" is the metastable state of the isotope \"xenon-134\" with a half-life of 3.36e-06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air.json index 595727460..86b8942ce 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_135Cs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"135Cs\" is the isotope \"cesium-135\" with a half-life of 8.39e+08 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135I_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135I_in_air.json index 08153417b..e116d804d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135I_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_135I_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_135I_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_135I_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"135I\" is the isotope \"iodine-135\" with a half-life of 2.79e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air.json index 8a73cb226..74a8c1bc5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_135Xe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"135Xe\" is the isotope \"xenon-135\" with a half-life of 3.82e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air.json index 7cc668144..60e82a0d8 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_135mBa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"135mBa\" is the metastable state of the isotope \"barium-135\" with a half-life of 1.20e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air.json index 8c2ef5c3a..996b55b5e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_135mCs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"135mCs\" is the metastable state of the isotope \"cesium-135\" with a half-life of 3.68e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air.json index 9f8b78c74..d09057bad 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_135mXe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"135mXe\" is the metastable state of the isotope \"xenon-135\" with a half-life of 1.08e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air.json index bcd1098ae..7d5aafb3a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_136Cs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"136Cs\" is the isotope \"cesium-136\" with a half-life of 1.30e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air.json index 51ded93cd..f3c928002 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_137Cs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"137Cs\" is the isotope \"cesium-137\" with a half-life of 1.10e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air.json index 8cdfdad8f..db93e2998 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_137Xe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"137Xe\" is the isotope \"xenon-137\" with a half-life of 2.71e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air.json index 1c988b528..57bbd55a7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_137mBa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"137mBa\" is the metastable state of the isotope \"barium-137\" with a half-life of 1.77e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air.json index 83346df74..da456f9ef 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_138Cs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"138Cs\" is the isotope \"cesium-138\" with a half-life of 2.23e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air.json index 7df4568e5..3d66bd4a1 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_138Xe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"138Xe\" is the isotope \"xenon-138\" with a half-life of 9.84e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air.json index 33ef4c8e0..8c2058335 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_139Ba_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"139Ba\" is the isotope \"barium-139\" with a half-life of 5.77e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_13N_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_13N_in_air.json index 242131aeb..3827d2f3b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_13N_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_13N_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_13N_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_13N_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_13N_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"N\" means the element \"nitrogen\" and \"13N\" is the isotope \"nitrogen-13\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air.json index 9898cbb00..b61e28df3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_140Ba_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"140Ba\" is the isotope \"barium-140\" with a half-life of 1.28e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140La_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140La_in_air.json index 46cd63640..d840d52e9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140La_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_140La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_140La_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_140La_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_140La_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"140La\" is the isotope \"lanthanum-140\" with a half-life of 1.76e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air.json index 06ed24ca6..2f485ed20 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_141Ce_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"141Ce\" is the isotope \"cerium-141\" with a half-life of 3.30e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141La_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141La_in_air.json index d24f7afa9..2ce0b3b15 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141La_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_141La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_141La_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_141La_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_141La_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"141La\" is the isotope \"lanthanum-141\" with a half-life of 1.61e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air.json index 5f05e08fb..f7865a065 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_142Ce_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"142Ce\" is the isotope \"cerium-142\" with a half-life of 1.82e+19 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142La_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142La_in_air.json index 4b64f77a1..84bcc7942 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142La_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_142La_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_142La_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_142La_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"142La\" is the isotope \"lanthanum-142\" with a half-life of 6.42e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air.json index 8a20b742b..827f7b360 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_142Pr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"142Pr\" is the isotope \"praseodymium-142\" with a half-life of 7.94e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air.json index 8187b8534..0598ce30c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_142mPr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"142mPr\" is the metastable state of the isotope \"praseodymium-142\" with a half-life of 1.01e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air.json index ad764606c..f1f7bfc77 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_143Ce_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"143Ce\" is the isotope \"cerium-143\" with a half-life of 1.37e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143La_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143La_in_air.json index ecb3a5e77..bca1f8fbb 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143La_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_143La_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_143La_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_143La_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"143La\" is the isotope \"lanthanum-143\" with a half-life of 9.72e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air.json index 76e75bf3f..778fe8208 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_143Pr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"143Pr\" is the isotope \"praseodymium-143\" with a half-life of 1.36e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air.json index 78f09921e..121840844 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_144Ce_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"144Ce\" is the isotope \"cerium-144\" with a half-life of 2.84e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air.json index 192eca205..a8f7bfb48 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_144Nd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"144Nd\" is the isotope \"neodymium-144\" with a half-life of 7.64e+17 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air.json index 69123b9d9..75a41cc37 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_144Pr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"144Pr\" is the isotope \"praseodymium-144\" with a half-life of 1.20e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air.json index e6fa3f2b1..931a8fd87 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_144mPr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"144mPr\" is the metastable state of the isotope \"praseodymium-144\" with a half-life of 4.98e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air.json index 41f9851db..8b6303650 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_145Pr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"145Pr\" is the isotope \"praseodymium-145\" with a half-life of 2.49e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air.json index 5ecf49cc8..5605c4772 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_146Ce_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"146Ce\" is the isotope \"cerium-146\" with a half-life of 9.86e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air.json index 7c641c282..a283474e4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_146Pr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"146Pr\" is the isotope \"praseodymium-146\" with a half-life of 1.68e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air.json index dc38eef9a..eeb40edfd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_147Nd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"147Nd\" is the isotope \"neodymium-147\" with a half-life of 1.10e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air.json index f4a0bc949..49b2cca91 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_147Pm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"147Pm\" is the isotope \"promethium-147\" with a half-life of 9.57e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air.json index 9b73a283b..03f44ad92 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_147Pr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"147Pr\" is the isotope \"praseodymium-147\" with a half-life of 8.33e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air.json index ff563c185..1048b6c92 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_147Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"147Sm\" is the isotope \"samarium-147\" with a half-life of 3.91e+13 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air.json index 3725c0dbc..c3c0f97c5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_148Pm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"148Pm\" is the isotope \"promethium-148\" with a half-life of 5.38e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air.json index 167c57487..194151b18 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_148Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"148Sm\" is the isotope \"samarium-148\" with a half-life of 2.92e+18 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air.json index 4452faa07..ca869bdbf 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_148mPm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"148mPm\" is the metastable state of the isotope \"promethium-148\" with a half-life of 4.14e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air.json index dcec10143..54485bfd6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_149Nd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"149Nd\" is the isotope \"neodymium-149\" with a half-life of 7.23e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air.json index dedc65d13..9ef5b2a3c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_149Pm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"149Pm\" is the isotope \"promethium-149\" with a half-life of 2.21e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air.json index 8206ed192..df008c6ab 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_149Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"149Sm\" is the isotope \"samarium-149\" with a half-life of 3.65e+18 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air.json index 7dc2fd66d..5df37419e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_150Pm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"150Pm\" is the isotope \"promethium-150\" with a half-life of 1.12e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air.json index c2aaf14f4..f88b52911 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_151Nd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"151Nd\" is the isotope \"neodymium-151\" with a half-life of 8.61e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air.json index 5d6185db3..28ef74c7a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_151Pm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"151Pm\" is the isotope \"promethium-151\" with a half-life of 1.18e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air.json index 046f78ccd..45911e120 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_151Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"151Sm\" is the isotope \"samarium-151\" with a half-life of 3.40e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air.json index a2f6eb726..172c33fb5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_152Nd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"152Nd\" is the isotope \"neodymium-152\" with a half-life of 7.94e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air.json index 1572983c3..8f51c11b3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_152Pm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"152Pm\" is the isotope \"promethium-152\" with a half-life of 2.84e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air.json index e7b482dcb..5206aac93 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_152mPm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"152mPm\" is the metastable state of the isotope \"promethium-152\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air.json index 17c0956d3..07892e76c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_153Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"153Sm\" is the isotope \"samarium-153\" with a half-life of 1.94e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air.json index 1075e3dd9..6d64f4a28 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_154Eu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"154Eu\" is the isotope \"europium-154\" with a half-life of 3.13e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air.json index cd5506147..a14c1a770 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_155Eu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"155Eu\" is the isotope \"europium-155\" with a half-life of 1.75e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air.json index 8b3047824..2715418ed 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_155Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"155Sm\" is the isotope \"samarium-155\" with a half-life of 1.54e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air.json index 9ddb2169a..1737176f6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_156Eu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"156Eu\" is the isotope \"europium-156\" with a half-life of 1.52e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air.json index ba3134c83..ab7f3d077 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_156Sm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"156Sm\" is the isotope \"samarium-156\" with a half-life of 3.91e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air.json index 11e7badb2..67aab4295 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_157Eu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"157Eu\" is the isotope \"europium-157\" with a half-life of 6.32e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air.json index 3625339c3..f0b76be32 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_158Eu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"158Eu\" is the isotope \"europium-158\" with a half-life of 3.18e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air.json index 25842662a..32cf6d187 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_159Eu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"159Eu\" is the isotope \"europium-159\" with a half-life of 1.26e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air.json index 3895215b7..c53ec1193 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_159Gd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Gd\" means the element \"gadolinium\" and \"159Gd\" is the isotope \"gadolinium-159\" with a half-life of 7.71e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_15O_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_15O_in_air.json index a50d1b4bb..83a5698a7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_15O_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_15O_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_15O_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_15O_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_15O_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"O\" means the element \"oxygen\" and \"15O\" is the isotope \"oxygen-15\" with a half-life of 1.41e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air.json index 01b49593d..23495102f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_160Tb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"160Tb\" is the isotope \"terbium-160\" with a half-life of 7.23e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air.json index 97c7f1388..752d4db05 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_161Tb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"161Tb\" is the isotope \"terbium-161\" with a half-life of 6.92e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air.json index 7c5a2937b..bb74ef7d2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_162Gd_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Gd\" means the element \"gadolinium\" and \"162Gd\" is the isotope \"gadolinium-162\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air.json index 124aef613..2f90d0c51 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_162Tb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"162Tb\" is the isotope \"terbium-162\" with a half-life of 5.18e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air.json index e908ff578..203db7c55 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_162mTb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"162mTb\" is the metastable state of the isotope \"terbium-162\" with a half-life of 9.30e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air.json index 7e0f79156..8db3f495a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_163Tb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"163Tb\" is the isotope \"terbium-163\" with a half-life of 1.36e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air.json index 2fac37afc..3f604eace 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_165Dy_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Dy\" means the element \"dysprosium\" and \"165Dy\" is the isotope \"dysprosium-165\" with a half-life of 9.80e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_18F_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_18F_in_air.json index f73b8804f..e8ceb03c5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_18F_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_18F_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_18F_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_18F_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_18F_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"F\" means the element \"fluorine\" and \"18F\" is the isotope \"fluorine-18\" with a half-life of 6.98e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air.json index c84de0c67..18175c151 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_206Hg_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Hg\" means the element \"mercury\" and \"206Hg\" is the isotope \"mercury-206\" with a half-life of 5.57e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air.json index 9a7071683..f92df7e70 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_206Tl_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"206Tl\" is the isotope \"thallium-206\" with a half-life of 2.91e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air.json index e6e5289dc..2a3c9a3db 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_207Tl_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"207Tl\" is the isotope \"thallium-207\" with a half-life of 3.33e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air.json index 2c48e768a..e322f9408 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_207mPb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"207mPb\" is the metastable state of the isotope \"lead-207\" with a half-life of 9.26e-06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air.json index b7c57b4c3..d5f5ba744 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_208Tl_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"208Tl\" is the isotope \"thallium-208\" with a half-life of 2.15e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air.json index 68f02f732..361290abe 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_209Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"209Bi\" is the isotope \"bismuth-209\" with a half-life of 7.29e+20 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air.json index cd92430d8..3a75963e0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_209Pb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"209Pb\" is the isotope \"lead-209\" with a half-life of 1.38e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air.json index f6b455eef..6f48d90a7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_209Tl_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"209Tl\" is the isotope \"thallium-209\" with a half-life of 1.53e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air.json index 313123fcf..377dfa8db 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_210Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"210Bi\" is the isotope \"bismuth-210\" with a half-life of 5.01e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air.json index af37d487d..d5a67207a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_210Pb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"210Pb\" is the isotope \"lead-210\" with a half-life of 7.64e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air.json index b05ec929a..73a90936b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_210Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"210Po\" is the isotope \"polonium-210\" with a half-life of 1.38e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air.json index 353e462c0..785770a81 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_210Tl_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"210Tl\" is the isotope \"thallium-210\" with a half-life of 9.02e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air.json index 91fd1a98d..e61e74288 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_211Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"211Bi\" is the isotope \"bismuth-211\" with a half-life of 1.49e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air.json index 1a35d86d2..d17ab333c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_211Pb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"211Pb\" is the isotope \"lead-211\" with a half-life of 2.51e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air.json index d3298fa6b..e2e2c98e2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_211Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"211Po\" is the isotope \"polonium-211\" with a half-life of 6.03e-06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air.json index 20505a7ad..a82fda337 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_212Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"212Bi\" is the isotope \"bismuth-212\" with a half-life of 4.20e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air.json index d6486bdee..fa06b659a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_212Pb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"212Pb\" is the isotope \"lead-212\" with a half-life of 4.43e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air.json index acb4eb7db..ebf73bb98 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_212Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"212Po\" is the isotope \"polonium-212\" with a half-life of 3.52e-12 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air.json index 0103f0d57..54497d913 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_213Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"213Bi\" is the isotope \"bismuth-213\" with a half-life of 3.26e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air.json index 4b31b8ef1..0c3ddab4f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_213Pb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"213Pb\" is the isotope \"lead-213\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air.json index d3aac241d..1d5a87daf 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_213Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"213Po\" is the isotope \"polonium-213\" with a half-life of 4.86e-11 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air.json index e0a617e61..a80fe822c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_214Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"214Bi\" is the isotope \"bismuth-214\" with a half-life of 1.37e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air.json index 222bad82b..56600dc73 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_214Pb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"214Pb\" is the isotope \"lead-214\" with a half-life of 1.86e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air.json index 8c0566b5c..6a3147f60 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_214Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"214Po\" is the isotope \"polonium-214\" with a half-life of 1.90e-09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215At_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215At_in_air.json index 7d485837b..75e3871d2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215At_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_215At_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_215At_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_215At_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"215At\" is the isotope \"astatine-215\" with a half-life of 1.16e-09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air.json index 16bba56b6..4c9ef8b4a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_215Bi_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"215Bi\" is the isotope \"bismuth-215\" with a half-life of 4.86e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air.json index 8c0ad89b3..36199fd09 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_215Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"215Po\" is the isotope \"polonium-215\" with a half-life of 2.06e-08 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216At_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216At_in_air.json index b96849e93..b0b046db1 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216At_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_216At_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_216At_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_216At_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"216At\" is the isotope \"astatine-216\" with a half-life of 3.47e-09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air.json index 1edeebb41..c7a76482c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_216Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"216Po\" is the isotope \"polonium-216\" with a half-life of 1.74e-06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217At_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217At_in_air.json index cdd1862ce..0ef69a64d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217At_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_217At_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_217At_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_217At_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"217At\" is the isotope \"astatine-217\" with a half-life of 3.70e-07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air.json index 46c1ab3b0..e11a0ba73 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_217Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"217Po\" is the isotope \"polonium-217\" with a half-life of 1.16e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218At_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218At_in_air.json index 2edb5cf88..288b33eba 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218At_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_218At_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_218At_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_218At_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"218At\" is the isotope \"astatine-218\" with a half-life of 2.31e-05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air.json index 922627181..8bbd8c001 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_218Po_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"218Po\" is the isotope \"polonium-218\" with a half-life of 2.12e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air.json index f65979ff0..39b1883c9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_218Rn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"218Rn\" is the isotope \"radon-218\" with a half-life of 4.05e-07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219At_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219At_in_air.json index 2aee6e7c4..b63b498b4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219At_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_219At_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_219At_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_219At_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"219At\" is the isotope \"astatine-219\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air.json index ff50d1693..393da1411 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_219Rn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"219Rn\" is the isotope \"radon-219\" with a half-life of 4.64e-05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air.json index 3baee4236..7bbe1c813 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_220Rn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"220Rn\" is the isotope \"radon-220\" with a half-life of 6.37e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air.json index 490a270f0..0dbd17f3c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_221Fr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Fr\" means the element \"francium\" and \"221Fr\" is the isotope \"francium-221\" with a half-life of 3.33e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air.json index d863bc490..60ebdb0e6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_221Rn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"221Rn\" is the isotope \"radon-221\" with a half-life of 1.74e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air.json index 2e86d104a..8c2e4e264 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_222Fr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Fr\" means the element \"francium\" and \"222Fr\" is the isotope \"francium-222\" with a half-life of 1.03e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air.json index 28d17b033..51eff5db6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_222Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"222Ra\" is the isotope \"radium-222\" with a half-life of 4.41e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air.json index 375cba5bc..6696d5114 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_222Rn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"222Rn\" is the isotope \"radon-222\" with a half-life of 3.82e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air.json index 9d43e944b..ad1d23eb3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_223Fr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Fr\" means the element \"francium\" and \"223Fr\" is the isotope \"francium-223\" with a half-life of 1.53e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air.json index 444d8e471..a1ef46141 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_223Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"223Ra\" is the isotope \"radium-223\" with a half-life of 1.14e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air.json index 6d2ca1b40..770a06a3b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_223Rn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"223Rn\" is the isotope \"radon-223\" with a half-life of 2.98e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air.json index 6c4e42208..123ac67e5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_224Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"224Ra\" is the isotope \"radium-224\" with a half-life of 3.65e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air.json index ca924cc78..5ba3b594b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_225Ac_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"225Ac\" is the isotope \"actinium-225\" with a half-life of 1.00e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air.json index 9294ed0d9..0e9fc2c36 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_225Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"225Ra\" is the isotope \"radium-225\" with a half-life of 1.48e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air.json index 055d41413..1390dd9ed 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_226Ac_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"226Ac\" is the isotope \"actinium-226\" with a half-life of 1.21e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air.json index 5703321fc..8cdf02606 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_226Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"226Ra\" is the isotope \"radium-226\" with a half-life of 5.86e+05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air.json index bff80bc99..3245df161 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_226Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"226Th\" is the isotope \"thorium-226\" with a half-life of 2.15e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air.json index 3248ea18b..4f4beada6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_227Ac_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"227Ac\" is the isotope \"actinium-227\" with a half-life of 7.87e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air.json index 10a9242e3..ec7e7311d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_227Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"227Ra\" is the isotope \"radium-227\" with a half-life of 2.87e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air.json index a82d6c63a..13b2f9955 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_227Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"227Th\" is the isotope \"thorium-227\" with a half-life of 1.82e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air.json index 07d89089f..3c862e9f9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_228Ac_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"228Ac\" is the isotope \"actinium-228\" with a half-life of 2.55e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air.json index a42d44684..2a69d1e2a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_228Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"228Ra\" is the isotope \"radium-228\" with a half-life of 2.45e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air.json index 06e7ecdba..74f5f5be6 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_228Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"228Th\" is the isotope \"thorium-228\" with a half-life of 6.98e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air.json index b3d80075a..e3640c7e2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_229Ac_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"229Ac\" is the isotope \"actinium-229\" with a half-life of 4.58e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air.json index d162f5ad3..dacf49d3a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_229Ra_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"229Ra\" is the isotope \"radium-229\" with a half-life of 1.16e-17 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air.json index 83d495418..027ac16ba 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_229Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"229Th\" is the isotope \"thorium-229\" with a half-life of 2.68e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air.json index 95f94624e..09201f9e5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_230Pa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"230Pa\" is the isotope \"protactinium-230\" with a half-life of 1.77e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air.json index 153548ad8..ca9f936a9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_230Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"230Th\" is the isotope \"thorium-230\" with a half-life of 2.92e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230U_in_air.json index e6e71a206..a0d56532a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_230U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_230U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_230U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_230U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"230U\" is the isotope \"uranium-230\" with a half-life of 2.08e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air.json index f1b8bd373..7cc91150a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_231Pa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"231Pa\" is the isotope \"protactinium-231\" with a half-life of 1.19e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air.json index bcd7dcfcb..b397502a9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_231Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"231Th\" is the isotope \"thorium-231\" with a half-life of 1.06e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231U_in_air.json index 6074f4e31..16c6dbc52 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_231U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_231U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_231U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_231U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"231U\" is the isotope \"uranium-231\" with a half-life of 4.29e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air.json index 6be91a86f..7f40513c1 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_232Pa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"232Pa\" is the isotope \"protactinium-232\" with a half-life of 1.31e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air.json index 46ca7b4d6..19b0206d2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_232Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"232Th\" is the isotope \"thorium-232\" with a half-life of 5.14e+12 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232U_in_air.json index fa8bb74e9..18fb67a1f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_232U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_232U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_232U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_232U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"232U\" is the isotope \"uranium-232\" with a half-life of 2.63e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air.json index 28b40e5f6..5ce2e136a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_233Pa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"233Pa\" is the isotope \"protactinium-233\" with a half-life of 2.70e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air.json index 6c39c6a72..8cb03d53d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_233Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"233Th\" is the isotope \"thorium-233\" with a half-life of 1.54e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233U_in_air.json index b8b0c0667..bd2a4b75f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_233U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_233U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_233U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_233U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"233U\" is the isotope \"uranium-233\" with a half-life of 5.90e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air.json index 56578901d..a9c99b229 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_234Pa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"234Pa\" is the isotope \"protactinium-234\" with a half-life of 2.81e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air.json index 7eb642096..d247332b9 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_234Th_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"234Th\" is the isotope \"thorium-234\" with a half-life of 2.41e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234U_in_air.json index 88d9055af..100cb3587 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_234U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_234U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_234U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"234U\" is the isotope \"uranium-234\" with a half-life of 9.02e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air.json index 05eb4f985..27483dc1e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_234mPa_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"234mPa\" is the metastable state of the isotope \"protactinium-234\" with a half-life of 8.13e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air.json index 5566d3c7a..71e64b558 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_235Np_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"235Np\" is the isotope \"neptunium-235\" with a half-life of 4.09e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air.json index 932f36ebf..51b520b4b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_235Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"235Pu\" is the isotope \"plutonium-235\" with a half-life of 1.81e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235U_in_air.json index 2c2a9337f..30627c2a4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_235U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_235U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_235U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_235U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"235U\" is the isotope \"uranium-235\" with a half-life of 2.60e+11 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air.json index 204d6dd77..ad930d214 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_236Np_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"236Np\" is the isotope \"neptunium-236\" with a half-life of 9.17e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air.json index 0abb50103..fb0df4f04 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_236Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"236Pu\" is the isotope \"plutonium-236\" with a half-life of 1.04e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236U_in_air.json index dbe2fb43b..cb26aebaf 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_236U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_236U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_236U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"236U\" is the isotope \"uranium-236\" with a half-life of 8.73e+09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air.json index 2bf90c3c5..a14d0d653 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_236mNp_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"236mNp\" is the metastable state of the isotope \"neptunium-236\" with a half-life of 4.72e+10 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air.json index 8758d0f2b..42db91651 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_237Np_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"237Np\" is the isotope \"neptunium-237\" with a half-life of 7.79e+08 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air.json index de5a7b88b..97a4af971 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_237Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"237Pu\" is the isotope \"plutonium-237\" with a half-life of 4.56e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237U_in_air.json index f50467d96..189d0660d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_237U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_237U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_237U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_237U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"237U\" is the isotope \"uranium-237\" with a half-life of 6.74e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air.json index 41e598423..123b0f184 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_238Np_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"238Np\" is the isotope \"neptunium-238\" with a half-life of 2.10e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air.json index dc39b017c..a8d23af21 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_238Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"238Pu\" is the isotope \"plutonium-238\" with a half-life of 3.15e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238U_in_air.json index 6fd91f61f..966b26696 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_238U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_238U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_238U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_238U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"238U\" is the isotope \"uranium-238\" with a half-life of 1.65e+12 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air.json index 0b98042fd..0424611e8 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_239Np_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"239Np\" is the isotope \"neptunium-239\" with a half-life of 2.35e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air.json index 9d7ef8943..9080ba54e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_239Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"239Pu\" is the isotope \"plutonium-239\" with a half-life of 8.91e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239U_in_air.json index f2c27f4e0..2889d84cc 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_239U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_239U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_239U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_239U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"239U\" is the isotope \"uranium-239\" with a half-life of 1.63e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air.json index 99f525f74..4826d312f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_240Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"240Am\" is the isotope \"americium-240\" with a half-life of 2.12e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air.json index e8b01d3e3..fb559ffda 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_240Np_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"240Np\" is the isotope \"neptunium-240\" with a half-life of 4.38e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air.json index 24cd1f5f8..b2d833c07 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_240Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"240Pu\" is the isotope \"plutonium-240\" with a half-life of 2.40e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240U_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240U_in_air.json index b69e3fb12..ff19fe259 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240U_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_240U_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_240U_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_240U_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"240U\" is the isotope \"uranium-240\" with a half-life of 5.99e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air.json index c7eb0f4b5..d6a9b2859 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_240mNp_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"240mNp\" is the metastable state of the isotope \"neptunium-240\" with a half-life of 5.08e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air.json index b4af4e3d7..7d792cacd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_241Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"241Am\" is the isotope \"americium-241\" with a half-life of 1.67e+05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air.json index 6369bd693..a9b7f41ae 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_241Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"241Cm\" is the isotope \"curium-241\" with a half-life of 3.50e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air.json index 9e71dd0cd..bde0c0830 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_241Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"241Pu\" is the isotope \"plutonium-241\" with a half-life of 4.83e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air.json index ce7eb111d..20e02ae8c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_242Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"242Am\" is the isotope \"americium-242\" with a half-life of 6.69e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air.json index 3d668ae4e..3205620da 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_242Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"242Cm\" is the isotope \"curium-242\" with a half-life of 1.63e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air.json index f42f4e5c8..8de40c19c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_242Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"242Pu\" is the isotope \"plutonium-242\" with a half-life of 1.38e+08 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air.json index ed2206b5d..8d86b5b73 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_242m1Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"242m1Am\" is the metastable state of the isotope \"americium-242\" with a half-life of 5.53e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air.json index 65145a668..69b115a25 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_242m2Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"242m2Am\" is the metastable state of the isotope \"americium-242\" with a half-life of 1.62e-07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air.json index 28e2346c6..4b2eac2a7 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_243Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"243Am\" is the isotope \"americium-243\" with a half-life of 2.91e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air.json index e2ce08c34..90aba946c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_243Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"243Cm\" is the isotope \"curium-243\" with a half-life of 1.17e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air.json index 7346c1b7e..2a774dc2f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_243Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"243Pu\" is the isotope \"plutonium-243\" with a half-life of 2.07e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air.json index 8d6ece5fb..11b8623dc 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_244Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"244Am\" is the isotope \"americium-244\" with a half-life of 4.20e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air.json index e6c9c46f6..41cb83434 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_244Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"244Cm\" is the isotope \"curium-244\" with a half-life of 6.42e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air.json index cd7960738..a4f4200cd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_244Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"244Pu\" is the isotope \"plutonium-244\" with a half-life of 2.92e+10 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air.json index fd7efbff0..e734a7388 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_244mAm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"244mAm\" is the metastable state of the isotope \"americium-244\" with a half-life of 1.81e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air.json index 1cd56287f..9b3f5ba8d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_245Am_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"245Am\" is the isotope \"americium-245\" with a half-life of 8.75e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air.json index d40a7631a..09791b104 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_245Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"245Cm\" is the isotope \"curium-245\" with a half-life of 3.40e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air.json index c57a069af..a4c98e665 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_245Pu_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"245Pu\" is the isotope \"plutonium-245\" with a half-life of 4.16e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air.json index b5d450da9..bdf701681 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_246Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"246Cm\" is the isotope \"curium-246\" with a half-life of 2.01e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air.json index 67edbf639..1fe075b62 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_247Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"247Cm\" is the isotope \"curium-247\" with a half-life of 5.86e+09 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air.json index 733ec9a6f..6bef8daba 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_248Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"248Cm\" is the isotope \"curium-248\" with a half-life of 1.72e+08 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air.json index 13aa57765..4235a9bde 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_249Bk_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bk\" means the element \"berkelium\" and \"249Bk\" is the isotope \"berkelium-249\" with a half-life of 3.15e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air.json index 112c89391..f48bc33c3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_249Cf_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"249Cf\" is the isotope \"californium-249\" with a half-life of 1.32e+05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air.json index 22c0a14db..d191dc113 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_249Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"249Cm\" is the isotope \"curium-249\" with a half-life of 4.43e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air.json index 72c7798ee..a2839c781 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_24Na_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Na\" means the element \"sodium\" and \"24Na\" is the isotope \"sodium-24\" with a half-life of 6.27e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air.json index a158c0b75..1022f2967 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_250Bk_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bk\" means the element \"berkelium\" and \"250Bk\" is the isotope \"berkelium-250\" with a half-life of 1.34e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air.json index bdc493094..81e5cde70 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_250Cf_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"250Cf\" is the isotope \"californium-250\" with a half-life of 4.75e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air.json index a771fc8f4..058a2e648 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_250Cm_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"250Cm\" is the isotope \"curium-250\" with a half-life of 2.52e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air.json index 478fde723..109a9e9c5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_251Cf_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"251Cf\" is the isotope \"californium-251\" with a half-life of 2.92e+05 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air.json index ebff0a560..0f6844e58 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_252Cf_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"252Cf\" is the isotope \"californium-252\" with a half-life of 9.68e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air.json index c0e918ebd..a14a23092 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_253Cf_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"253Cf\" is the isotope \"californium-253\" with a half-life of 1.76e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air.json index e26090c59..eda640a88 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_253Es_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"253Es\" is the isotope \"einsteinium-253\" with a half-life of 2.05e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air.json index 0a688bb66..44c4bc4e0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_254Cf_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"254Cf\" is the isotope \"californium-254\" with a half-life of 6.03e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air.json index e5f2cc4a1..503c30b03 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_254Es_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"254Es\" is the isotope \"einsteinium-254\" with a half-life of 2.76e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air.json index be694f857..a8ff89aab 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_254mEs_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"254mEs\" is the metastable state of the isotope \"einsteinium-254\" with a half-life of 1.63e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air.json index 1e94c20e0..304569e03 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_255Es_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"255Es\" is the isotope \"einsteinium-255\" with a half-life of 3.84e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_3H_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_3H_in_air.json index ff4ee70b2..aee10ea56 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_3H_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_3H_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_3H_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_3H_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_3H_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"H\" means the element \"hydrogen\" and \"3H\" is the isotope \"hydrogen-3\" with a half-life of 4.51e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air.json index 71cef9591..e45b732ba 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_41Ar_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ar\" means the element \"argon\" and \"41Ar\" is the isotope \"argon-41\" with a half-life of 7.64e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air.json index 9c989f30b..0a9446a5e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_54Mn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mn\" means the element \"manganese\" and \"54Mn\" is the isotope \"manganese-54\" with a half-life of 3.12e+02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air.json index 8e886373a..c18a3bdc8 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_58Co_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Co\" means the element \"cobalt\" and \"58Co\" is the isotope \"cobalt-58\" with a half-life of 7.10e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air.json index ae8df814a..d4a1186b4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_60Co_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Co\" means the element \"cobalt\" and \"60Co\" is the isotope \"cobalt-60\" with a half-life of 1.93e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air.json index e5d258ae1..e246472eb 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_72Ga_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ga\" means the element \"gallium\" and \"72Ga\" is the isotope \"gallium-72\" with a half-life of 5.86e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air.json index 360e759fd..acf73bde1 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_72Zn_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zn\" means the element \"zinc\" and \"72Zn\" is the isotope \"zinc-72\" with a half-life of 1.94e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air.json index 9af875b25..aa789a669 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_73Ga_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ga\" means the element \"gallium\" and \"73Ga\" is the isotope \"gallium-73\" with a half-life of 2.03e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air.json index a558c7ce9..94ada0119 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_75Ge_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"75Ge\" is the isotope \"germanium-75\" with a half-life of 5.73e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77As_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77As_in_air.json index c4bcfc687..bc8402aff 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77As_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77As_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_77As_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_77As_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_77As_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"As\" means the element \"arsenic\" and \"77As\" is the isotope \"arsenic-77\" with a half-life of 1.62e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air.json index adc9acca0..d1f4a25ba 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_77Ge_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"77Ge\" is the isotope \"germanium-77\" with a half-life of 4.72e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air.json index 6a6629127..d52d93ed0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_77mGe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"77mGe\" is the metastable state of the isotope \"germanium-77\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78As_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78As_in_air.json index cb8ea1260..63a6721fa 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78As_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78As_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_78As_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_78As_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_78As_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"As\" means the element \"arsenic\" and \"78As\" is the isotope \"arsenic-78\" with a half-life of 6.32e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air.json index 69e5276b2..020d03585 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_78Ge_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"78Ge\" is the isotope \"germanium-78\" with a half-life of 6.03e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air.json index 85df02e2f..171aaf22e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_79Se_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"79Se\" is the isotope \"selenium-79\" with a half-life of 2.37e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air.json index 9b16ee8cf..1ead4ff3c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_81Se_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"81Se\" is the isotope \"selenium-81\" with a half-life of 1.28e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air.json index 4fb0328ee..83c80e072 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_81mSe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"81mSe\" is the metastable state of the isotope \"selenium-81\" with a half-life of 3.97e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air.json index bc5980ce3..edbbaffe3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_82Br_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"82Br\" is the isotope \"bromine-82\" with a half-life of 1.47e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air.json index 0d4827f3e..cfbbfeb35 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_82mBr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"82mBr\" is the metastable state of the isotope \"bromine-82\" with a half-life of 4.24e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air.json index 0d94ed8e2..c31ca1b0f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_83Br_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"83Br\" is the isotope \"bromine-83\" with a half-life of 1.00e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air.json index 7d1c283d9..5cf2bb292 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_83Se_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"83Se\" is the isotope \"selenium-83\" with a half-life of 1.56e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air.json index 023ba1965..d7e5655cb 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_83mKr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"83mKr\" is the metastable state of the isotope \"krypton-83\" with a half-life of 7.71e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air.json index f254593ef..b47e2a507 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_83mSe_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"83mSe\" is the metastable state of the isotope \"selenium-83\" with a half-life of 8.10e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air.json index e9f201ead..c844fbafe 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_84Br_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"84Br\" is the isotope \"bromine-84\" with a half-life of 2.21e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air.json index bdc0cefd2..2975743c0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_84mBr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"84mBr\" is the metastable state of the isotope \"bromine-84\" with a half-life of 4.16e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air.json index 0277f41b8..bb7c2a78a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_85Kr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"85Kr\" is the isotope \"krypton-85\" with a half-life of 3.95e+03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air.json index 6b5a7b963..7001113c3 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_85mKr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"85mKr\" is the metastable state of the isotope \"krypton-85\" with a half-life of 1.83e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air.json index 7611f5c97..eaf14c139 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_86Rb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"86Rb\" is the isotope \"rubidium-86\" with a half-life of 1.87e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air.json index dc541ecce..efc1ddf38 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_86mRb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"86mRb\" is the metastable state of the isotope \"rubidium-86\" with a half-life of 7.04e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air.json index 5fb4bce57..834748e9d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_87Kr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"87Kr\" is the isotope \"krypton-87\" with a half-life of 5.28e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air.json index 371d7db7a..f4b3977ce 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_87Rb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"87Rb\" is the isotope \"rubidium-87\" with a half-life of 1.71e+13 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air.json index e8f5bf1bb..66a330972 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_88Kr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"88Kr\" is the isotope \"krypton-88\" with a half-life of 1.17e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air.json index 572397f7e..19e53110f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_88Rb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"88Rb\" is the isotope \"rubidium-88\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air.json index c0854ab71..eeb8f2655 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_89Kr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"89Kr\" is the isotope \"krypton-89\" with a half-life of 2.20e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air.json index b629cbea7..788407dbd 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_89Rb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"89Rb\" is the isotope \"rubidium-89\" with a half-life of 1.06e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air.json index f65b02176..d186974f0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_89Sr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"89Sr\" is the isotope \"strontium-89\" with a half-life of 5.21e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air.json index ccee682bb..29769bc01 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_90Sr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"90Sr\" is the isotope \"strontium-90\" with a half-life of 1.02e+04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air.json index 395673412..7d72af17b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_90Y_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"90Y\" is the isotope \"yttrium-90\" with a half-life of 2.67e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air.json index aa4f22b32..1d7a5ac9d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_90mY_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"90mY\" is the metastable state of the isotope \"yttrium-90\" with a half-life of 1.33e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air.json index d9f17c153..4668bf65a 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_91Sr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"91Sr\" is the isotope \"strontium-91\" with a half-life of 3.95e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air.json index b8059d045..d8ad4ef13 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_91Y_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"91Y\" is the isotope \"yttrium-91\" with a half-life of 5.86e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air.json index 35ca783b5..487213fc5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_91mY_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"91mY\" is the metastable state of the isotope \"yttrium-91\" with a half-life of 3.46e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air.json index dbd15263a..a057b1b66 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_92Sr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"92Sr\" is the isotope \"strontium-92\" with a half-life of 1.13e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air.json index e11f5e42d..438b31bca 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_92Y_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"92Y\" is the isotope \"yttrium-92\" with a half-life of 1.47e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air.json index a137c6579..2c28d8dfe 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_93Y_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"93Y\" is the isotope \"yttrium-93\" with a half-life of 4.24e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air.json index c291c916a..1596e100e 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_93Zr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zr\" means the element \"zirconium\" and \"93Zr\" is the isotope \"zirconium-93\" with a half-life of 3.47e+08 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air.json index 560a9865a..7da838f1d 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_94Nb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"94Nb\" is the isotope \"niobium-94\" with a half-life of 7.29e+06 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air.json index e258c7d58..6f4d073c8 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_94Y_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"94Y\" is the isotope \"yttrium-94\" with a half-life of 1.32e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air.json index 827cc09e9..abcac96b2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_94mNb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"94mNb\" is the metastable state of the isotope \"niobium-94\" with a half-life of 4.34e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air.json index c70374582..552d4dda5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_95Nb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"95Nb\" is the isotope \"niobium-95\" with a half-life of 3.52e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air.json index 45727fffb..7aaa7c8d0 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_95Y_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"95Y\" is the isotope \"yttrium-95\" with a half-life of 7.29e-03 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air.json index 43e2338dd..692699736 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_95Zr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zr\" means the element \"zirconium\" and \"95Zr\" is the isotope \"zirconium-95\" with a half-life of 6.52e+01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air.json index 757e418c3..60d3b713f 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_95mNb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"95mNb\" is the metastable state of the isotope \"niobium-95\" with a half-life of 3.61e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air.json index 04727ce08..6da422231 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_96Nb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"96Nb\" is the isotope \"niobium-96\" with a half-life of 9.75e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air.json index 28d351db0..8aa9ceb74 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_97Nb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"97Nb\" is the isotope \"niobium-97\" with a half-life of 5.11e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air.json index 999891117..cd57f35f4 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_97Zr_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zr\" means the element \"zirconium\" and \"97Zr\" is the isotope \"zirconium-97\" with a half-life of 6.98e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air.json index fbac51889..eb36eef72 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_97mNb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"97mNb\" is the metastable state of the isotope \"niobium-97\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air.json index 2cd425a05..e65a19071 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_98Nb_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"98Nb\" is the isotope \"niobium-98\" with a half-life of 3.53e-02 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air.json index d63619f9b..95316a287 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_99Mo_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mo\" means the element \"molybdenum\" and \"99Mo\" is the isotope \"molybdenum-99\" with a half-life of 2.78e+00 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air.json index b5b57a29d..9412530e2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_99Tc_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"99Tc\" is the isotope \"technetium-99\" with a half-life of 7.79e+07 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air.json index f1a1b7235..219257474 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air", + "id": "integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air", "type": "standard_name", "name": "integral_wrt_time_of_radioactivity_concentration_of_99mTc_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means \"with respect to\". \"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"99mTc\" is the metastable state of the isotope \"technetium-99\" with a half-life of 2.51e-01 days.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_eastward_stress.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_eastward_stress.json index 99d955d6c..5d34ef9ab 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_eastward_stress.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_eastward_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_downward_eastward_stress", + "id": "integral_wrt_time_of_surface_downward_eastward_stress", "type": "standard_name", "name": "integral_wrt_time_of_surface_downward_eastward_stress", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The abbreviation \"wrt\" means \"with respect to\". The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_latent_heat_flux.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_latent_heat_flux.json index 68a5849c0..17e9b84e2 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_latent_heat_flux.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_latent_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_downward_latent_heat_flux", + "id": "integral_wrt_time_of_surface_downward_latent_heat_flux", "type": "standard_name", "name": "integral_wrt_time_of_surface_downward_latent_heat_flux", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_northward_stress.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_northward_stress.json index 405d7567b..e17fd93f5 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_northward_stress.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_northward_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_downward_northward_stress", + "id": "integral_wrt_time_of_surface_downward_northward_stress", "type": "standard_name", "name": "integral_wrt_time_of_surface_downward_northward_stress", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The abbreviation \"wrt\" means \"with respect to\". The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_sensible_heat_flux.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_sensible_heat_flux.json index 9e04284f8..dcb3c084b 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_sensible_heat_flux.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_downward_sensible_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_downward_sensible_heat_flux", + "id": "integral_wrt_time_of_surface_downward_sensible_heat_flux", "type": "standard_name", "name": "integral_wrt_time_of_surface_downward_sensible_heat_flux", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface sensible heat flux, also called \"turbulent\" heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_longwave_flux_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_longwave_flux_in_air.json index 73b55137d..1008f8953 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_downwelling_longwave_flux_in_air", + "id": "integral_wrt_time_of_surface_downwelling_longwave_flux_in_air", "type": "standard_name", "name": "integral_wrt_time_of_surface_downwelling_longwave_flux_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air.json index b14890ec2..c81d643b8 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air", + "id": "integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "integral_wrt_time_of_surface_downwelling_shortwave_flux_in_air", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. The phrase \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. Surface downwelling shortwave is the sum of direct and diffuse solar radiation incident on the surface, and is sometimes called \"global radiation\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_longwave_flux.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_longwave_flux.json index cc54861bc..53b02d70c 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_longwave_flux.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_net_downward_longwave_flux", + "id": "integral_wrt_time_of_surface_net_downward_longwave_flux", "type": "standard_name", "name": "integral_wrt_time_of_surface_net_downward_longwave_flux", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). \"longwave\" means longwave radiation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_shortwave_flux.json b/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_shortwave_flux.json index 9c21ea972..5866117bc 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_shortwave_flux.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_surface_net_downward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_surface_net_downward_shortwave_flux", + "id": "integral_wrt_time_of_surface_net_downward_shortwave_flux", "type": "standard_name", "name": "integral_wrt_time_of_surface_net_downward_shortwave_flux", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). \"Shortwave\" means shortwave radiation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_toa_net_downward_shortwave_flux.json b/data_descriptors/standard_name/integral_wrt_time_of_toa_net_downward_shortwave_flux.json index dcd51f228..a2e4bc448 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_toa_net_downward_shortwave_flux.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_toa_net_downward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_toa_net_downward_shortwave_flux", + "id": "integral_wrt_time_of_toa_net_downward_shortwave_flux", "type": "standard_name", "name": "integral_wrt_time_of_toa_net_downward_shortwave_flux", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. \"toa\" means top of atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). \"Shortwave\" means shortwave radiation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/integral_wrt_time_of_toa_outgoing_longwave_flux.json b/data_descriptors/standard_name/integral_wrt_time_of_toa_outgoing_longwave_flux.json index 1246aa549..05ce25708 100644 --- a/data_descriptors/standard_name/integral_wrt_time_of_toa_outgoing_longwave_flux.json +++ b/data_descriptors/standard_name/integral_wrt_time_of_toa_outgoing_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/integral_wrt_time_of_toa_outgoing_longwave_flux", + "id": "integral_wrt_time_of_toa_outgoing_longwave_flux", "type": "standard_name", "name": "integral_wrt_time_of_toa_outgoing_longwave_flux", "description": "The phrase \"integral_wrt_X_of_Y\" means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. \"wrt\" means with respect to. \"toa\" means top of atmosphere. \"Longwave\" means longwave radiation. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/iron_growth_limitation_of_calcareous_phytoplankton.json b/data_descriptors/standard_name/iron_growth_limitation_of_calcareous_phytoplankton.json index 15461eb45..6ca661e9e 100644 --- a/data_descriptors/standard_name/iron_growth_limitation_of_calcareous_phytoplankton.json +++ b/data_descriptors/standard_name/iron_growth_limitation_of_calcareous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/iron_growth_limitation_of_calcareous_phytoplankton", + "id": "iron_growth_limitation_of_calcareous_phytoplankton", "type": "standard_name", "name": "iron_growth_limitation_of_calcareous_phytoplankton", "description": "\"Calcareous phytoplankton\" are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Iron growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", diff --git a/data_descriptors/standard_name/iron_growth_limitation_of_diatoms.json b/data_descriptors/standard_name/iron_growth_limitation_of_diatoms.json index afc0a6081..b80b53646 100644 --- a/data_descriptors/standard_name/iron_growth_limitation_of_diatoms.json +++ b/data_descriptors/standard_name/iron_growth_limitation_of_diatoms.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/iron_growth_limitation_of_diatoms", + "id": "iron_growth_limitation_of_diatoms", "type": "standard_name", "name": "iron_growth_limitation_of_diatoms", "description": "Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Iron growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", diff --git a/data_descriptors/standard_name/iron_growth_limitation_of_diazotrophic_phytoplankton.json b/data_descriptors/standard_name/iron_growth_limitation_of_diazotrophic_phytoplankton.json index 1d2f09404..199cddc62 100644 --- a/data_descriptors/standard_name/iron_growth_limitation_of_diazotrophic_phytoplankton.json +++ b/data_descriptors/standard_name/iron_growth_limitation_of_diazotrophic_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/iron_growth_limitation_of_diazotrophic_phytoplankton", + "id": "iron_growth_limitation_of_diazotrophic_phytoplankton", "type": "standard_name", "name": "iron_growth_limitation_of_diazotrophic_phytoplankton", "description": "\"Iron growth limitation\" means the ratio of the growth rate of a biological population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/iron_growth_limitation_of_miscellaneous_phytoplankton.json b/data_descriptors/standard_name/iron_growth_limitation_of_miscellaneous_phytoplankton.json index d815a62b0..a69747c3e 100644 --- a/data_descriptors/standard_name/iron_growth_limitation_of_miscellaneous_phytoplankton.json +++ b/data_descriptors/standard_name/iron_growth_limitation_of_miscellaneous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/iron_growth_limitation_of_miscellaneous_phytoplankton", + "id": "iron_growth_limitation_of_miscellaneous_phytoplankton", "type": "standard_name", "name": "iron_growth_limitation_of_miscellaneous_phytoplankton", "description": "Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. \"Iron growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", diff --git a/data_descriptors/standard_name/iron_growth_limitation_of_picophytoplankton.json b/data_descriptors/standard_name/iron_growth_limitation_of_picophytoplankton.json index cea9b95aa..45f220e48 100644 --- a/data_descriptors/standard_name/iron_growth_limitation_of_picophytoplankton.json +++ b/data_descriptors/standard_name/iron_growth_limitation_of_picophytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/iron_growth_limitation_of_picophytoplankton", + "id": "iron_growth_limitation_of_picophytoplankton", "type": "standard_name", "name": "iron_growth_limitation_of_picophytoplankton", "description": "Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Iron growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", diff --git a/data_descriptors/standard_name/isccp_cloud_area_fraction.json b/data_descriptors/standard_name/isccp_cloud_area_fraction.json index af0cfcb95..2635da500 100644 --- a/data_descriptors/standard_name/isccp_cloud_area_fraction.json +++ b/data_descriptors/standard_name/isccp_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/isccp_cloud_area_fraction", + "id": "isccp_cloud_area_fraction", "type": "standard_name", "name": "isccp_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names also exist for high, medium and low cloud types. The ISCCP cloud area fraction is diagnosed from atmosphere model output by the ISCCP simulator software in such a way as to be comparable with the observational diagnostics of ISCCP (the International Satellite Cloud Climatology Project). Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids.json b/data_descriptors/standard_name/isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids.json index 1eca6aff3..d5d10cbef 100644 --- a/data_descriptors/standard_name/isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids.json +++ b/data_descriptors/standard_name/isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids", + "id": "isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids", "type": "standard_name", "name": "isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids", "description": "The phrase \"ratio_of_X_to_Y\" means X/Y. The phrase \"isotope_ratio\" is used in the construction isotope_ratio_of_A_to_B where A and B are both named isotopes. It means the ratio of the number of atoms of A to the number of atoms of B present within a medium. \"O\" means the element \"oxygen\" and \"17O\" is the stable isotope \"oxygen-17\". \"16O\" is the stable isotope \"oxygen-16\". The phrase \"in_sea_water_excluding_solutes_and_solids\" means that the standard name refers only to the chemical compound water and does not include material that may be dissolved or suspended in the aqueous medium.", diff --git a/data_descriptors/standard_name/isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids.json b/data_descriptors/standard_name/isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids.json index d1a5a7921..510550a1e 100644 --- a/data_descriptors/standard_name/isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids.json +++ b/data_descriptors/standard_name/isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids", + "id": "isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids", "type": "standard_name", "name": "isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids", "description": "The phrase \"ratio_of_X_to_Y\" means X/Y. The phrase \"isotope_ratio\" is used in the construction isotope_ratio_of_A_to_B where A and B are both named isotopes. It means the ratio of the number of atoms of A to the number of atoms of B present within a medium. \"O\" means the element \"oxygen\" and \"18O\" is the stable isotope \"oxygen-18\". \"16O\" is the stable isotope \"oxygen-16\". The phrase \"in_sea_water_excluding_solutes_and_solids\" means that the standard name refers only to the chemical compound water and does not include material that may be dissolved or suspended in the aqueous medium.", diff --git a/data_descriptors/standard_name/isotropic_longwave_radiance_in_air.json b/data_descriptors/standard_name/isotropic_longwave_radiance_in_air.json index 32ad072fd..2f4a094b9 100644 --- a/data_descriptors/standard_name/isotropic_longwave_radiance_in_air.json +++ b/data_descriptors/standard_name/isotropic_longwave_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/isotropic_longwave_radiance_in_air", + "id": "isotropic_longwave_radiance_in_air", "type": "standard_name", "name": "isotropic_longwave_radiance_in_air", "description": "\"longwave\" means longwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. If radiation is isotropic, the radiance is independent of direction, so the direction should not be specified. If the radiation is directionally dependent, a standard name of upwelling or downwelling radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/isotropic_radiance_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/isotropic_radiance_per_unit_wavelength_in_air.json index a42d0ca28..6738c3b3d 100644 --- a/data_descriptors/standard_name/isotropic_radiance_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/isotropic_radiance_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/isotropic_radiance_per_unit_wavelength_in_air", + "id": "isotropic_radiance_per_unit_wavelength_in_air", "type": "standard_name", "name": "isotropic_radiance_per_unit_wavelength_in_air", "description": "Radiance is the radiative flux in a particular direction, per unit of solid angle. If radiation is isotropic, the radiance is independent of direction, so the direction should not be specified. If the radiation is directionally dependent, a standard name of upwelling or downwelling radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/isotropic_shortwave_radiance_in_air.json b/data_descriptors/standard_name/isotropic_shortwave_radiance_in_air.json index 8212fd4cc..f2b1ba070 100644 --- a/data_descriptors/standard_name/isotropic_shortwave_radiance_in_air.json +++ b/data_descriptors/standard_name/isotropic_shortwave_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/isotropic_shortwave_radiance_in_air", + "id": "isotropic_shortwave_radiance_in_air", "type": "standard_name", "name": "isotropic_shortwave_radiance_in_air", "description": "\"shortwave\" means shortwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. If radiation is isotropic, the radiance is independent of direction, so the direction should not be specified. If the radiation is directionally dependent, a standard name of upwelling or downwelling radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/keetch_byram_drought_index.json b/data_descriptors/standard_name/keetch_byram_drought_index.json index 28478e4a9..de7ee33ce 100644 --- a/data_descriptors/standard_name/keetch_byram_drought_index.json +++ b/data_descriptors/standard_name/keetch_byram_drought_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/keetch_byram_drought_index", + "id": "keetch_byram_drought_index", "type": "standard_name", "name": "keetch_byram_drought_index", "description": "The Keetch Byram Drought Index (KBDI) is a numerical drought index ranging from 0 to 800 that estimates the cumulative moisture deficiency in soil. It is a cumulative index. It is a function of maximum temperature and precipitation over the previous 24 hours.", diff --git a/data_descriptors/standard_name/kinetic_energy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/kinetic_energy_content_of_atmosphere_layer.json index 2567ddd1a..16c8508c6 100644 --- a/data_descriptors/standard_name/kinetic_energy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/kinetic_energy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/kinetic_energy_content_of_atmosphere_layer", + "id": "kinetic_energy_content_of_atmosphere_layer", "type": "standard_name", "name": "kinetic_energy_content_of_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/kinetic_energy_dissipation_in_atmosphere_boundary_layer.json b/data_descriptors/standard_name/kinetic_energy_dissipation_in_atmosphere_boundary_layer.json index 70a26b300..34cc410b8 100644 --- a/data_descriptors/standard_name/kinetic_energy_dissipation_in_atmosphere_boundary_layer.json +++ b/data_descriptors/standard_name/kinetic_energy_dissipation_in_atmosphere_boundary_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/kinetic_energy_dissipation_in_atmosphere_boundary_layer", + "id": "kinetic_energy_dissipation_in_atmosphere_boundary_layer", "type": "standard_name", "name": "kinetic_energy_dissipation_in_atmosphere_boundary_layer", "description": null, diff --git a/data_descriptors/standard_name/lagrangian_tendency_of_air_pressure.json b/data_descriptors/standard_name/lagrangian_tendency_of_air_pressure.json index 46dfb2e97..873e86899 100644 --- a/data_descriptors/standard_name/lagrangian_tendency_of_air_pressure.json +++ b/data_descriptors/standard_name/lagrangian_tendency_of_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lagrangian_tendency_of_air_pressure", + "id": "lagrangian_tendency_of_air_pressure", "type": "standard_name", "name": "lagrangian_tendency_of_air_pressure", "description": "\"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/lagrangian_tendency_of_atmosphere_sigma_coordinate.json b/data_descriptors/standard_name/lagrangian_tendency_of_atmosphere_sigma_coordinate.json index 87cdabced..e1a0f5eb1 100644 --- a/data_descriptors/standard_name/lagrangian_tendency_of_atmosphere_sigma_coordinate.json +++ b/data_descriptors/standard_name/lagrangian_tendency_of_atmosphere_sigma_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lagrangian_tendency_of_atmosphere_sigma_coordinate", + "id": "lagrangian_tendency_of_atmosphere_sigma_coordinate", "type": "standard_name", "name": "lagrangian_tendency_of_atmosphere_sigma_coordinate", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of sigma plays the role of the upward component of air velocity when the atmosphere sigma coordinate (a dimensionless atmosphere vertical coordinate) is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of sigma; downwards is positive. See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/land_area_fraction.json b/data_descriptors/standard_name/land_area_fraction.json index b76145728..1a565f516 100644 --- a/data_descriptors/standard_name/land_area_fraction.json +++ b/data_descriptors/standard_name/land_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_area_fraction", + "id": "land_area_fraction", "type": "standard_name", "name": "land_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/land_binary_mask.json b/data_descriptors/standard_name/land_binary_mask.json index 6640c1d92..5837c3f3a 100644 --- a/data_descriptors/standard_name/land_binary_mask.json +++ b/data_descriptors/standard_name/land_binary_mask.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_binary_mask", + "id": "land_binary_mask", "type": "standard_name", "name": "land_binary_mask", "description": "X_binary_mask has 1 where condition X is met, 0 elsewhere. 1 = land, 0 = sea.", diff --git a/data_descriptors/standard_name/land_cover_lccs.json b/data_descriptors/standard_name/land_cover_lccs.json index 539612009..c400acf07 100644 --- a/data_descriptors/standard_name/land_cover_lccs.json +++ b/data_descriptors/standard_name/land_cover_lccs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_cover_lccs", + "id": "land_cover_lccs", "type": "standard_name", "name": "land_cover_lccs", "description": "A variable with the standard name of land_cover_lccs contains strings which indicate the nature of the surface, e.g. cropland_..., tree_... . Each string should represent a land cover class constructed using the Land Cover Classification System (LCCS; Di Gregorio A., 2005, UN Land Cover Classification System (LCCS) - Classification concepts and user manual for Software version 2; available at www.fao.org/DOCREP/003/X0596E/X0596e00.htm). String values should represent the classifiers used to define each class.", diff --git a/data_descriptors/standard_name/land_ice_area_fraction.json b/data_descriptors/standard_name/land_ice_area_fraction.json index afa1f327e..ddd3ae74e 100644 --- a/data_descriptors/standard_name/land_ice_area_fraction.json +++ b/data_descriptors/standard_name/land_ice_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_area_fraction", + "id": "land_ice_area_fraction", "type": "standard_name", "name": "land_ice_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/land_ice_basal_drag.json b/data_descriptors/standard_name/land_ice_basal_drag.json index 3073bfe1a..1668c9a4d 100644 --- a/data_descriptors/standard_name/land_ice_basal_drag.json +++ b/data_descriptors/standard_name/land_ice_basal_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_drag", + "id": "land_ice_basal_drag", "type": "standard_name", "name": "land_ice_basal_drag", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. Basal drag is a resistive stress opposing ice flow at the ice bedrock boundary.", diff --git a/data_descriptors/standard_name/land_ice_basal_melt_rate.json b/data_descriptors/standard_name/land_ice_basal_melt_rate.json index 224974601..d06a8b0a6 100644 --- a/data_descriptors/standard_name/land_ice_basal_melt_rate.json +++ b/data_descriptors/standard_name/land_ice_basal_melt_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_melt_rate", + "id": "land_ice_basal_melt_rate", "type": "standard_name", "name": "land_ice_basal_melt_rate", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The land ice basal melt rate is the rate at which ice is lost per unit area at the base of the ice.", diff --git a/data_descriptors/standard_name/land_ice_basal_specific_mass_balance_flux.json b/data_descriptors/standard_name/land_ice_basal_specific_mass_balance_flux.json index d268fb8ff..669d57843 100644 --- a/data_descriptors/standard_name/land_ice_basal_specific_mass_balance_flux.json +++ b/data_descriptors/standard_name/land_ice_basal_specific_mass_balance_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_specific_mass_balance_flux", + "id": "land_ice_basal_specific_mass_balance_flux", "type": "standard_name", "name": "land_ice_basal_specific_mass_balance_flux", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Specific mass balance\" means the net rate at which ice is added per unit area. A negative value means loss of ice. For an area-average, the cell_methods attribute should be used to specify whether the average is over the area of the whole grid cell or the area of land ice only. \"Basal specific mass balance\" means the net rate at which ice is added per unit area at the land ice base.", diff --git a/data_descriptors/standard_name/land_ice_basal_temperature.json b/data_descriptors/standard_name/land_ice_basal_temperature.json index 4a663434c..0fab878f0 100644 --- a/data_descriptors/standard_name/land_ice_basal_temperature.json +++ b/data_descriptors/standard_name/land_ice_basal_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_temperature", + "id": "land_ice_basal_temperature", "type": "standard_name", "name": "land_ice_basal_temperature", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The standard name land_ice_basal_temperature means the temperature of the land ice at its lower boundary. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/land_ice_basal_upward_velocity.json b/data_descriptors/standard_name/land_ice_basal_upward_velocity.json index 1dbb6950d..7a1e3bf32 100644 --- a/data_descriptors/standard_name/land_ice_basal_upward_velocity.json +++ b/data_descriptors/standard_name/land_ice_basal_upward_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_upward_velocity", + "id": "land_ice_basal_upward_velocity", "type": "standard_name", "name": "land_ice_basal_upward_velocity", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward).", diff --git a/data_descriptors/standard_name/land_ice_basal_x_velocity.json b/data_descriptors/standard_name/land_ice_basal_x_velocity.json index 8ca4b50d2..41a44a509 100644 --- a/data_descriptors/standard_name/land_ice_basal_x_velocity.json +++ b/data_descriptors/standard_name/land_ice_basal_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_x_velocity", + "id": "land_ice_basal_x_velocity", "type": "standard_name", "name": "land_ice_basal_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/land_ice_basal_y_velocity.json b/data_descriptors/standard_name/land_ice_basal_y_velocity.json index 6f7bba24e..0c2d6dd9c 100644 --- a/data_descriptors/standard_name/land_ice_basal_y_velocity.json +++ b/data_descriptors/standard_name/land_ice_basal_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_basal_y_velocity", + "id": "land_ice_basal_y_velocity", "type": "standard_name", "name": "land_ice_basal_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/land_ice_calving_rate.json b/data_descriptors/standard_name/land_ice_calving_rate.json index f61586d1d..86603da28 100644 --- a/data_descriptors/standard_name/land_ice_calving_rate.json +++ b/data_descriptors/standard_name/land_ice_calving_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_calving_rate", + "id": "land_ice_calving_rate", "type": "standard_name", "name": "land_ice_calving_rate", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The land ice calving rate is the rate at which ice is lost per unit area through calving into the ocean.", diff --git a/data_descriptors/standard_name/land_ice_lwe_basal_melt_rate.json b/data_descriptors/standard_name/land_ice_lwe_basal_melt_rate.json index 90c37e240..07df82d88 100644 --- a/data_descriptors/standard_name/land_ice_lwe_basal_melt_rate.json +++ b/data_descriptors/standard_name/land_ice_lwe_basal_melt_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_lwe_basal_melt_rate", + "id": "land_ice_lwe_basal_melt_rate", "type": "standard_name", "name": "land_ice_lwe_basal_melt_rate", "description": "\"lwe\" means liquid water equivalent. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The land ice basal melt rate is the rate at which ice is lost per unit area at the base of the ice.", diff --git a/data_descriptors/standard_name/land_ice_lwe_calving_rate.json b/data_descriptors/standard_name/land_ice_lwe_calving_rate.json index 4c82929f2..e69e6a3c9 100644 --- a/data_descriptors/standard_name/land_ice_lwe_calving_rate.json +++ b/data_descriptors/standard_name/land_ice_lwe_calving_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_lwe_calving_rate", + "id": "land_ice_lwe_calving_rate", "type": "standard_name", "name": "land_ice_lwe_calving_rate", "description": "\"lwe\" means liquid water equivalent. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The land ice calving rate is the rate at which ice is lost per unit area through calving into the ocean.", diff --git a/data_descriptors/standard_name/land_ice_lwe_surface_specific_mass_balance_rate.json b/data_descriptors/standard_name/land_ice_lwe_surface_specific_mass_balance_rate.json index f2794d7d9..974dc11b9 100644 --- a/data_descriptors/standard_name/land_ice_lwe_surface_specific_mass_balance_rate.json +++ b/data_descriptors/standard_name/land_ice_lwe_surface_specific_mass_balance_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_lwe_surface_specific_mass_balance_rate", + "id": "land_ice_lwe_surface_specific_mass_balance_rate", "type": "standard_name", "name": "land_ice_lwe_surface_specific_mass_balance_rate", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"lwe\" means liquid water equivalent. Specific mass balance means the net rate at which ice is added per unit area at the land ice surface due to all processes of surface accumulation and ablation. A negative value means loss of ice.", diff --git a/data_descriptors/standard_name/land_ice_mass.json b/data_descriptors/standard_name/land_ice_mass.json index 01d567643..88d129f21 100644 --- a/data_descriptors/standard_name/land_ice_mass.json +++ b/data_descriptors/standard_name/land_ice_mass.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_mass", + "id": "land_ice_mass", "type": "standard_name", "name": "land_ice_mass", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The horizontal domain over which the quantity is calculated is described by the associated coordinate variables and coordinate bounds or by a coordinate variable or scalar coordinate variable with the standard name of \"region\" supplied according to section 6.1.1 of the CF conventions.", diff --git a/data_descriptors/standard_name/land_ice_mass_not_displacing_sea_water.json b/data_descriptors/standard_name/land_ice_mass_not_displacing_sea_water.json index 469ef32db..7c45f2f25 100644 --- a/data_descriptors/standard_name/land_ice_mass_not_displacing_sea_water.json +++ b/data_descriptors/standard_name/land_ice_mass_not_displacing_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_mass_not_displacing_sea_water", + "id": "land_ice_mass_not_displacing_sea_water", "type": "standard_name", "name": "land_ice_mass_not_displacing_sea_water", "description": "\"Land ice not displacing sea water\" means land ice that would alter sea level if the ice were converted to water and added to the ocean. It excludes ice shelves (and any other sort of floating ice) and it excludes a fraction of grounded ice-sheet mass equivalent to the mass of any sea water it displaces. It includes glaciers and a portion of grounded ice-sheet mass exceeding the mass of any sea water displaced. The quantity with standard name land_ice_mass_not_displacing_sea_water is the total mass integrated over an area of land ice. The geographical extent of the ice over which the mass was calculated should be described by providing bounds on the horizontal coordinate variable or scalar with the standard name of \"region\" supplied according to section 6.1.1 of the CF convention. \"Land ice not displacing sea water\" is sometimes referred to as \"ice above flotation\" or \"ice above floatation\".", diff --git a/data_descriptors/standard_name/land_ice_runoff_flux.json b/data_descriptors/standard_name/land_ice_runoff_flux.json index a46126e71..1d07a5d02 100644 --- a/data_descriptors/standard_name/land_ice_runoff_flux.json +++ b/data_descriptors/standard_name/land_ice_runoff_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_runoff_flux", + "id": "land_ice_runoff_flux", "type": "standard_name", "name": "land_ice_runoff_flux", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage. Runoff flux over land ice is the difference between any available liquid water in the snowpack due to rainfall and melting minus any refreezing and liquid water retained in the snowpack. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/land_ice_sigma_coordinate.json b/data_descriptors/standard_name/land_ice_sigma_coordinate.json index 36feb93cd..6a7980b24 100644 --- a/data_descriptors/standard_name/land_ice_sigma_coordinate.json +++ b/data_descriptors/standard_name/land_ice_sigma_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_sigma_coordinate", + "id": "land_ice_sigma_coordinate", "type": "standard_name", "name": "land_ice_sigma_coordinate", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving.json b/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving.json index b7b8a7592..b5f7b6b59 100644 --- a/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving.json +++ b/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_specific_mass_flux_due_to_calving", + "id": "land_ice_specific_mass_flux_due_to_calving", "type": "standard_name", "name": "land_ice_specific_mass_flux_due_to_calving", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"Specific mass flux due to calving\" means the change in land ice mass per unit area resulting from iceberg calving. A negative value means loss of ice. For an area-average, the cell_methods attribute should be used to specify whether the average is over the area of the whole grid cell or the area of land ice only. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting.json b/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting.json index 9eef4ed04..cb0af332e 100644 --- a/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting.json +++ b/data_descriptors/standard_name/land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", + "id": "land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", "type": "standard_name", "name": "land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Specific mass flux due to calving and ice front melting\" means the change in land ice mass per unit area resulting from iceberg calving and melting on the vertical ice front. A negative value means loss of ice. For an area-average, the cell_methods attribute should be used to specify whether the average is over the area of the whole grid cell or the area of land ice only. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/land_ice_surface_melt_flux.json b/data_descriptors/standard_name/land_ice_surface_melt_flux.json index 84c1db9eb..19551990e 100644 --- a/data_descriptors/standard_name/land_ice_surface_melt_flux.json +++ b/data_descriptors/standard_name/land_ice_surface_melt_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_surface_melt_flux", + "id": "land_ice_surface_melt_flux", "type": "standard_name", "name": "land_ice_surface_melt_flux", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The land_ice_surface_melt_flux is the loss of ice mass resulting from surface melting. For an area-average, the cell_methods attribute should be used to specify whether the average is over the area of the whole grid cell or the area of land ice only. There is also a standard name for the quantity surface_snow_and_ice_melt_flux.", diff --git a/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_flux.json b/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_flux.json index 6464f241f..2dcb9a47a 100644 --- a/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_flux.json +++ b/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_surface_specific_mass_balance_flux", + "id": "land_ice_surface_specific_mass_balance_flux", "type": "standard_name", "name": "land_ice_surface_specific_mass_balance_flux", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Specific mass balance\" means the net rate at which ice is added per unit area. A negative value means loss of ice. For an area-average, the cell_methods attribute should be used to specify whether the average is over the area of the whole grid cell or the area of land ice only. \"Surface specific mass balance\" means the net rate at which ice is added per unit area at the land ice surface due to all processes of surface accumulation and ablation.", diff --git a/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_rate.json b/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_rate.json index c1691b6fb..93702c2ce 100644 --- a/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_rate.json +++ b/data_descriptors/standard_name/land_ice_surface_specific_mass_balance_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_surface_specific_mass_balance_rate", + "id": "land_ice_surface_specific_mass_balance_rate", "type": "standard_name", "name": "land_ice_surface_specific_mass_balance_rate", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. Specific mass balance means the net rate at which ice is added at the land ice surface due to all processes of surface accumulation and ablation. A negative value means loss of ice.", diff --git a/data_descriptors/standard_name/land_ice_surface_upward_velocity.json b/data_descriptors/standard_name/land_ice_surface_upward_velocity.json index 472c3b8a1..ad4f2dd07 100644 --- a/data_descriptors/standard_name/land_ice_surface_upward_velocity.json +++ b/data_descriptors/standard_name/land_ice_surface_upward_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_surface_upward_velocity", + "id": "land_ice_surface_upward_velocity", "type": "standard_name", "name": "land_ice_surface_upward_velocity", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/land_ice_surface_x_velocity.json b/data_descriptors/standard_name/land_ice_surface_x_velocity.json index e4f99ab1c..8d67c472b 100644 --- a/data_descriptors/standard_name/land_ice_surface_x_velocity.json +++ b/data_descriptors/standard_name/land_ice_surface_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_surface_x_velocity", + "id": "land_ice_surface_x_velocity", "type": "standard_name", "name": "land_ice_surface_x_velocity", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/land_ice_surface_y_velocity.json b/data_descriptors/standard_name/land_ice_surface_y_velocity.json index 1854a2ae1..1f4e3c744 100644 --- a/data_descriptors/standard_name/land_ice_surface_y_velocity.json +++ b/data_descriptors/standard_name/land_ice_surface_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_surface_y_velocity", + "id": "land_ice_surface_y_velocity", "type": "standard_name", "name": "land_ice_surface_y_velocity", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/land_ice_temperature.json b/data_descriptors/standard_name/land_ice_temperature.json index 2367e5c55..1f4dabf4a 100644 --- a/data_descriptors/standard_name/land_ice_temperature.json +++ b/data_descriptors/standard_name/land_ice_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_temperature", + "id": "land_ice_temperature", "type": "standard_name", "name": "land_ice_temperature", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/land_ice_thickness.json b/data_descriptors/standard_name/land_ice_thickness.json index d28dd57d8..a7cbf93d9 100644 --- a/data_descriptors/standard_name/land_ice_thickness.json +++ b/data_descriptors/standard_name/land_ice_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_thickness", + "id": "land_ice_thickness", "type": "standard_name", "name": "land_ice_thickness", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/land_ice_vertical_mean_x_velocity.json b/data_descriptors/standard_name/land_ice_vertical_mean_x_velocity.json index 0b29b28ea..7b7c16131 100644 --- a/data_descriptors/standard_name/land_ice_vertical_mean_x_velocity.json +++ b/data_descriptors/standard_name/land_ice_vertical_mean_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_vertical_mean_x_velocity", + "id": "land_ice_vertical_mean_x_velocity", "type": "standard_name", "name": "land_ice_vertical_mean_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The vertical mean land ice velocity is the average from the bedrock to the surface of the ice.", diff --git a/data_descriptors/standard_name/land_ice_vertical_mean_y_velocity.json b/data_descriptors/standard_name/land_ice_vertical_mean_y_velocity.json index 815fe16d9..a7b7d535b 100644 --- a/data_descriptors/standard_name/land_ice_vertical_mean_y_velocity.json +++ b/data_descriptors/standard_name/land_ice_vertical_mean_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_vertical_mean_y_velocity", + "id": "land_ice_vertical_mean_y_velocity", "type": "standard_name", "name": "land_ice_vertical_mean_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The vertical mean land ice velocity is the average from the bedrock to the surface of the ice.", diff --git a/data_descriptors/standard_name/land_ice_x_velocity.json b/data_descriptors/standard_name/land_ice_x_velocity.json index 77b5c1832..64c86afeb 100644 --- a/data_descriptors/standard_name/land_ice_x_velocity.json +++ b/data_descriptors/standard_name/land_ice_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_x_velocity", + "id": "land_ice_x_velocity", "type": "standard_name", "name": "land_ice_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/land_ice_y_velocity.json b/data_descriptors/standard_name/land_ice_y_velocity.json index 016708344..42a4c03a0 100644 --- a/data_descriptors/standard_name/land_ice_y_velocity.json +++ b/data_descriptors/standard_name/land_ice_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_ice_y_velocity", + "id": "land_ice_y_velocity", "type": "standard_name", "name": "land_ice_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/land_surface_liquid_water_amount.json b/data_descriptors/standard_name/land_surface_liquid_water_amount.json index b9166d10a..17284c671 100644 --- a/data_descriptors/standard_name/land_surface_liquid_water_amount.json +++ b/data_descriptors/standard_name/land_surface_liquid_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_surface_liquid_water_amount", + "id": "land_surface_liquid_water_amount", "type": "standard_name", "name": "land_surface_liquid_water_amount", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Amount\" means mass per unit area. The quantity with standard name land_surface_liquid_water_amount includes water in rivers, wetlands, lakes, reservoirs and liquid precipitation intercepted by the vegetation canopy.", diff --git a/data_descriptors/standard_name/land_water_amount.json b/data_descriptors/standard_name/land_water_amount.json index a2ed02be9..abc957b25 100644 --- a/data_descriptors/standard_name/land_water_amount.json +++ b/data_descriptors/standard_name/land_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/land_water_amount", + "id": "land_water_amount", "type": "standard_name", "name": "land_water_amount", "description": "\"Amount\" means mass per unit area. \"Water\" means water in all phases. The phrase \"land_water_amount\", often known as \"Terrestrial Water Storage\", includes: surface liquid water (water in rivers, wetlands, lakes, reservoirs, rainfall intercepted by the canopy); surface ice and snow (glaciers, ice caps, grounded ice sheets not displacing sea water, river and lake ice, other surface ice such as frozen flood water, snow lying on the surface and intercepted by the canopy); subsurface water (liquid and frozen soil water, groundwater).", diff --git a/data_descriptors/standard_name/latitude.json b/data_descriptors/standard_name/latitude.json index 904c45eea..4542660c2 100644 --- a/data_descriptors/standard_name/latitude.json +++ b/data_descriptors/standard_name/latitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/latitude", + "id": "latitude", "type": "standard_name", "name": "latitude", "description": "Latitude is positive northward; its units of degree_north (or equivalent) indicate this explicitly. In a latitude-longitude system defined with respect to a rotated North Pole, the standard name of grid_latitude should be used instead of latitude. Grid latitude is positive in the grid-northward direction, but its units should be plain degree.", diff --git a/data_descriptors/standard_name/leaf_area_index.json b/data_descriptors/standard_name/leaf_area_index.json index d7086d9e7..11ca38bbb 100644 --- a/data_descriptors/standard_name/leaf_area_index.json +++ b/data_descriptors/standard_name/leaf_area_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/leaf_area_index", + "id": "leaf_area_index", "type": "standard_name", "name": "leaf_area_index", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell.", diff --git a/data_descriptors/standard_name/leaf_mass_content_of_carbon.json b/data_descriptors/standard_name/leaf_mass_content_of_carbon.json index 50d666406..d46aecf2f 100644 --- a/data_descriptors/standard_name/leaf_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/leaf_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/leaf_mass_content_of_carbon", + "id": "leaf_mass_content_of_carbon", "type": "standard_name", "name": "leaf_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area.", diff --git a/data_descriptors/standard_name/leaf_mass_content_of_nitrogen.json b/data_descriptors/standard_name/leaf_mass_content_of_nitrogen.json index f44ec82d5..4f53a66c8 100644 --- a/data_descriptors/standard_name/leaf_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/leaf_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/leaf_mass_content_of_nitrogen", + "id": "leaf_mass_content_of_nitrogen", "type": "standard_name", "name": "leaf_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area.", diff --git a/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json index 05e970f83..6fdeb8152 100644 --- a/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", + "id": "left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "left_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "description": "Left singular vectors of the matrix representing the logarithmic scale remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (fractional changes of methane in the retrieved atmosphere relative to the fractional changes of methane in the true atmosphere, Rodgers 2000; Keppens et al., 2015).", diff --git a/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json index 104d5922a..8f854b5a9 100644 --- a/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", + "id": "left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "left_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "description": "Left singular vectors of the matrix representing the remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000).", diff --git a/data_descriptors/standard_name/lightning_potential_index.json b/data_descriptors/standard_name/lightning_potential_index.json index 469a82932..7b2bc8bc8 100644 --- a/data_descriptors/standard_name/lightning_potential_index.json +++ b/data_descriptors/standard_name/lightning_potential_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lightning_potential_index", + "id": "lightning_potential_index", "type": "standard_name", "name": "lightning_potential_index", "description": "The lightning_potential_index measures the potential for charge generation and separation that leads to lightning flashes in convective thunderstorms. It is derived from the model simulated grid-scale updraft velocity and the mass mixing-ratios of liquid water, cloud ice, snow, and graupel.", diff --git a/data_descriptors/standard_name/lightning_radiant_energy.json b/data_descriptors/standard_name/lightning_radiant_energy.json index 0ac95cca9..70385d9e7 100644 --- a/data_descriptors/standard_name/lightning_radiant_energy.json +++ b/data_descriptors/standard_name/lightning_radiant_energy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lightning_radiant_energy", + "id": "lightning_radiant_energy", "type": "standard_name", "name": "lightning_radiant_energy", "description": "The standard name \"lightning radiant energy\" means the energy emitted as electromagnetic radiation due to lightning. A coordinate variable of radiation_wavelength, radiation_frequency, or sensor_band_central_wavelength may be specified to indicate that the lightning_radiant_energy applies at specific wavelengths or frequencies. Bounds of the time and spatial coordinates may be specified to indicate the time interval and spatial extent over which the energy is emitted.", diff --git a/data_descriptors/standard_name/liquid_water_cloud_area_fraction.json b/data_descriptors/standard_name/liquid_water_cloud_area_fraction.json index 07fc8aead..78f71c745 100644 --- a/data_descriptors/standard_name/liquid_water_cloud_area_fraction.json +++ b/data_descriptors/standard_name/liquid_water_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/liquid_water_cloud_area_fraction", + "id": "liquid_water_cloud_area_fraction", "type": "standard_name", "name": "liquid_water_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names also exist for high, medium and low cloud types. \"Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/liquid_water_cloud_area_fraction_in_atmosphere_layer.json b/data_descriptors/standard_name/liquid_water_cloud_area_fraction_in_atmosphere_layer.json index cdd61d51d..ebc08e18d 100644 --- a/data_descriptors/standard_name/liquid_water_cloud_area_fraction_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/liquid_water_cloud_area_fraction_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/liquid_water_cloud_area_fraction_in_atmosphere_layer", + "id": "liquid_water_cloud_area_fraction_in_atmosphere_layer", "type": "standard_name", "name": "liquid_water_cloud_area_fraction_in_atmosphere_layer", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Standard names also exist for high, medium and low cloud types. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/liquid_water_content_of_permafrost_layer.json b/data_descriptors/standard_name/liquid_water_content_of_permafrost_layer.json index 881aaa482..2ff2b8d0a 100644 --- a/data_descriptors/standard_name/liquid_water_content_of_permafrost_layer.json +++ b/data_descriptors/standard_name/liquid_water_content_of_permafrost_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/liquid_water_content_of_permafrost_layer", + "id": "liquid_water_content_of_permafrost_layer", "type": "standard_name", "name": "liquid_water_content_of_permafrost_layer", "description": "\"Content\" indicates a quantity per unit area. Permafrost is soil or rock that has remained at a temperature at or below zero degrees Celsius throughout the seasonal cycle for two or more years.", diff --git a/data_descriptors/standard_name/liquid_water_content_of_soil_layer.json b/data_descriptors/standard_name/liquid_water_content_of_soil_layer.json index b9a266f3d..383147bfa 100644 --- a/data_descriptors/standard_name/liquid_water_content_of_soil_layer.json +++ b/data_descriptors/standard_name/liquid_water_content_of_soil_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/liquid_water_content_of_soil_layer", + "id": "liquid_water_content_of_soil_layer", "type": "standard_name", "name": "liquid_water_content_of_soil_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).", diff --git a/data_descriptors/standard_name/liquid_water_content_of_surface_snow.json b/data_descriptors/standard_name/liquid_water_content_of_surface_snow.json index 17aa6cf71..c2b7b0788 100644 --- a/data_descriptors/standard_name/liquid_water_content_of_surface_snow.json +++ b/data_descriptors/standard_name/liquid_water_content_of_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/liquid_water_content_of_surface_snow", + "id": "liquid_water_content_of_surface_snow", "type": "standard_name", "name": "liquid_water_content_of_surface_snow", "description": "\"Content\" indicates a quantity per unit area. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/liquid_water_mass_flux_into_soil_due_to_surface_snow_melt.json b/data_descriptors/standard_name/liquid_water_mass_flux_into_soil_due_to_surface_snow_melt.json index 6469eb212..025cf47f5 100644 --- a/data_descriptors/standard_name/liquid_water_mass_flux_into_soil_due_to_surface_snow_melt.json +++ b/data_descriptors/standard_name/liquid_water_mass_flux_into_soil_due_to_surface_snow_melt.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/liquid_water_mass_flux_into_soil_due_to_surface_snow_melt", + "id": "liquid_water_mass_flux_into_soil_due_to_surface_snow_melt", "type": "standard_name", "name": "liquid_water_mass_flux_into_soil_due_to_surface_snow_melt", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/litter_mass_content_of_13C.json b/data_descriptors/standard_name/litter_mass_content_of_13C.json index bc347d7f8..298835f1b 100644 --- a/data_descriptors/standard_name/litter_mass_content_of_13C.json +++ b/data_descriptors/standard_name/litter_mass_content_of_13C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/litter_mass_content_of_13C", + "id": "litter_mass_content_of_13C", "type": "standard_name", "name": "litter_mass_content_of_13C", "description": "\"Content\" indicates a quantity per unit area. \"Litter\" is dead plant material in or above the soil. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/litter_mass_content_of_14C.json b/data_descriptors/standard_name/litter_mass_content_of_14C.json index 8045db6ed..b0f8003af 100644 --- a/data_descriptors/standard_name/litter_mass_content_of_14C.json +++ b/data_descriptors/standard_name/litter_mass_content_of_14C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/litter_mass_content_of_14C", + "id": "litter_mass_content_of_14C", "type": "standard_name", "name": "litter_mass_content_of_14C", "description": "\"Content\" indicates a quantity per unit area. \"Litter\" is dead plant material in or above the soil. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/litter_mass_content_of_carbon.json b/data_descriptors/standard_name/litter_mass_content_of_carbon.json index 2cc1ee169..c42a87d29 100644 --- a/data_descriptors/standard_name/litter_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/litter_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/litter_mass_content_of_carbon", + "id": "litter_mass_content_of_carbon", "type": "standard_name", "name": "litter_mass_content_of_carbon", "description": "\"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. \"Content\" indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", diff --git a/data_descriptors/standard_name/litter_mass_content_of_nitrogen.json b/data_descriptors/standard_name/litter_mass_content_of_nitrogen.json index bbaff2cd0..fbda94ae6 100644 --- a/data_descriptors/standard_name/litter_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/litter_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/litter_mass_content_of_nitrogen", + "id": "litter_mass_content_of_nitrogen", "type": "standard_name", "name": "litter_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The sum of the quantities with standard names surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen has the standard name litter_mass_content_of_nitrogen.", diff --git a/data_descriptors/standard_name/location_test_quality_flag.json b/data_descriptors/standard_name/location_test_quality_flag.json index 101435e8e..a2c3ea565 100644 --- a/data_descriptors/standard_name/location_test_quality_flag.json +++ b/data_descriptors/standard_name/location_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/location_test_quality_flag", + "id": "location_test_quality_flag", "type": "standard_name", "name": "location_test_quality_flag", "description": "A quality flag that reports the result of the Location test, which checks that a location is within reasonable bounds. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air.json b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air.json index 5d351f741..3874d90a8 100644 --- a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air.json +++ b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air", + "id": "log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air", "type": "standard_name", "name": "log10_size_interval_based_number_size_distribution_of_aerosol_particles_at_stp_in_air", "description": "The aerosol particle number size distribution is the number concentration of aerosol particles, normalised to the decadal logarithmic size interval the concentration applies to, as a function of particle diameter. A coordinate variable with the standard name of electrical_mobility_particle_diameter, aerodynamic_particle_diameter, or optical_particle_diameter should be specified to indicate that the property applies at specific particle sizes selected by the indicated method. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. \"log10_X\" means common logarithm (i.e. base 10) of X. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa).", diff --git a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air.json b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air.json index 52a2b30c0..9b085f7d5 100644 --- a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air", + "id": "log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air", "type": "standard_name", "name": "log10_size_interval_based_number_size_distribution_of_aerosol_particles_in_air", "description": "The aerosol particle number size distribution is the number concentration of aerosol particles, normalised to the decadal logarithmic size interval the concentration applies to, as a function of particle diameter. A coordinate variable with the standard name of electrical_mobility_particle_diameter, aerodynamic_particle_diameter, or optical_particle_diameter should be specified to indicate that the property applies at specific particle sizes selected by the indicated method. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. \"log10_X\" means common logarithm (i.e. base 10) of X.", diff --git a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json index be3ab8eef..44dbb6017 100644 --- a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json +++ b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air", + "id": "log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air", "type": "standard_name", "name": "log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air", "description": "The cloud condensation nuclei number size distribution is the number concentration of aerosol particles, normalised to the decadal logarithmic size interval the concentration applies to, as a function of particle diameter, where the particle acts as condensation nucleus for liquid-phase clouds. A coordinate variable with the standard name of relative_humidity should be specified to indicate that the property refers to a specific supersaturation with respect to liquid water. A coordinate variable with the standard name of electrical_mobility_particle_diameter should be specified to indicate that the property applies at specific mobility particle sizes. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. The ability of a particle to act as a condensation nucleus is determined by its size, chemical composition, and morphology. \"log10_X\" means common logarithm (i.e. base 10) of X. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa).", diff --git a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air.json b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air.json index 37141042d..2fadd4760 100644 --- a/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air.json +++ b/data_descriptors/standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air", + "id": "log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air", "type": "standard_name", "name": "log10_size_interval_based_number_size_distribution_of_cloud_condensation_nuclei_in_air", "description": "The cloud condensation nuclei number size distribution is the number concentration of aerosol particles, normalised to the decadal logarithmic size interval the concentration applies to, as a function of particle diameter, where the particle acts as condensation nucleus for liquid-phase clouds. A coordinate variable with the standard name of relative_humidity should be specified to indicate that the property refers to a specific supersaturation with respect to liquid water. A coordinate variable with the standard name of electrical_mobility_particle_diameter should be specified to indicate that the property applies at specific mobility particle sizes. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. The ability of a particle to act as a condensation nucleus is determined by its size, chemical composition, and morphology. \"log10_X\" means common logarithm (i.e. base 10) of X.", diff --git a/data_descriptors/standard_name/longitude.json b/data_descriptors/standard_name/longitude.json index 74eef9fd7..b1dcf596a 100644 --- a/data_descriptors/standard_name/longitude.json +++ b/data_descriptors/standard_name/longitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/longitude", + "id": "longitude", "type": "standard_name", "name": "longitude", "description": "Longitude is positive eastward; its units of degree_east (or equivalent) indicate this explicitly. In a latitude-longitude system defined with respect to a rotated North Pole, the standard name of grid_longitude should be used instead of longitude. Grid longitude is positive in the grid-eastward direction, but its units should be plain degree.", diff --git a/data_descriptors/standard_name/low_type_cloud_area_fraction.json b/data_descriptors/standard_name/low_type_cloud_area_fraction.json index 43d493dc2..72c847c03 100644 --- a/data_descriptors/standard_name/low_type_cloud_area_fraction.json +++ b/data_descriptors/standard_name/low_type_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/low_type_cloud_area_fraction", + "id": "low_type_cloud_area_fraction", "type": "standard_name", "name": "low_type_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Low type clouds are: Stratus, Stratocumulus, Cumulus, Cumulonimbus. X_type_cloud_area_fraction is generally determined on the basis of cloud type, though Numerical Weather Prediction (NWP) models often calculate them based on the vertical location of the cloud. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/lwe_convective_precipitation_rate.json b/data_descriptors/standard_name/lwe_convective_precipitation_rate.json index 00e838db3..c4252c5b0 100644 --- a/data_descriptors/standard_name/lwe_convective_precipitation_rate.json +++ b/data_descriptors/standard_name/lwe_convective_precipitation_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_convective_precipitation_rate", + "id": "lwe_convective_precipitation_rate", "type": "standard_name", "name": "lwe_convective_precipitation_rate", "description": "Convective precipitation is that produced by the convection schemes in an atmosphere model. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent. \"Precipitation rate\" means the depth or thickness of the layer formed by precipitation per unit time.", diff --git a/data_descriptors/standard_name/lwe_convective_snowfall_rate.json b/data_descriptors/standard_name/lwe_convective_snowfall_rate.json index b77f56371..9e1b81480 100644 --- a/data_descriptors/standard_name/lwe_convective_snowfall_rate.json +++ b/data_descriptors/standard_name/lwe_convective_snowfall_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_convective_snowfall_rate", + "id": "lwe_convective_snowfall_rate", "type": "standard_name", "name": "lwe_convective_snowfall_rate", "description": "\"lwe\" means liquid water equivalent.", diff --git a/data_descriptors/standard_name/lwe_precipitation_rate.json b/data_descriptors/standard_name/lwe_precipitation_rate.json index 3e46c43ad..d4dc95ac7 100644 --- a/data_descriptors/standard_name/lwe_precipitation_rate.json +++ b/data_descriptors/standard_name/lwe_precipitation_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_precipitation_rate", + "id": "lwe_precipitation_rate", "type": "standard_name", "name": "lwe_precipitation_rate", "description": "\"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent. \"Precipitation rate\" means the depth or thickness of the layer formed by precipitation per unit time.", diff --git a/data_descriptors/standard_name/lwe_snowfall_rate.json b/data_descriptors/standard_name/lwe_snowfall_rate.json index 4e560ca34..0f50e08d4 100644 --- a/data_descriptors/standard_name/lwe_snowfall_rate.json +++ b/data_descriptors/standard_name/lwe_snowfall_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_snowfall_rate", + "id": "lwe_snowfall_rate", "type": "standard_name", "name": "lwe_snowfall_rate", "description": "\"lwe\" means liquid water equivalent.", diff --git a/data_descriptors/standard_name/lwe_stratiform_precipitation_rate.json b/data_descriptors/standard_name/lwe_stratiform_precipitation_rate.json index d01850403..bd790a798 100644 --- a/data_descriptors/standard_name/lwe_stratiform_precipitation_rate.json +++ b/data_descriptors/standard_name/lwe_stratiform_precipitation_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_stratiform_precipitation_rate", + "id": "lwe_stratiform_precipitation_rate", "type": "standard_name", "name": "lwe_stratiform_precipitation_rate", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent. \"Precipitation rate\" means the depth or thickness of the layer formed by precipitation per unit time.", diff --git a/data_descriptors/standard_name/lwe_stratiform_snowfall_rate.json b/data_descriptors/standard_name/lwe_stratiform_snowfall_rate.json index abc56bb73..643ff31a7 100644 --- a/data_descriptors/standard_name/lwe_stratiform_snowfall_rate.json +++ b/data_descriptors/standard_name/lwe_stratiform_snowfall_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_stratiform_snowfall_rate", + "id": "lwe_stratiform_snowfall_rate", "type": "standard_name", "name": "lwe_stratiform_snowfall_rate", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"lwe\" means liquid water equivalent.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_atmosphere_mass_content_of_water_vapor.json b/data_descriptors/standard_name/lwe_thickness_of_atmosphere_mass_content_of_water_vapor.json index 3ebcf8abb..5c6bdacdc 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_atmosphere_mass_content_of_water_vapor.json +++ b/data_descriptors/standard_name/lwe_thickness_of_atmosphere_mass_content_of_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_atmosphere_mass_content_of_water_vapor", + "id": "lwe_thickness_of_atmosphere_mass_content_of_water_vapor", "type": "standard_name", "name": "lwe_thickness_of_atmosphere_mass_content_of_water_vapor", "description": "\"lwe\" means liquid water equivalent. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_canopy_water_amount.json b/data_descriptors/standard_name/lwe_thickness_of_canopy_water_amount.json index 96c8b7f7c..a94ad2aae 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_canopy_water_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_canopy_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_canopy_water_amount", + "id": "lwe_thickness_of_canopy_water_amount", "type": "standard_name", "name": "lwe_thickness_of_canopy_water_amount", "description": "The abbreviation \"lwe\" means liquid water equivalent. \"Amount\" means mass per unit area. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Water\" means water in all phases, including frozen i.e. ice and snow. The canopy water is the water on the canopy. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_convective_precipitation_amount.json b/data_descriptors/standard_name/lwe_thickness_of_convective_precipitation_amount.json index cf0dde791..ce9b8a182 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_convective_precipitation_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_convective_precipitation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_convective_precipitation_amount", + "id": "lwe_thickness_of_convective_precipitation_amount", "type": "standard_name", "name": "lwe_thickness_of_convective_precipitation_amount", "description": "The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. Convective precipitation is that produced by the convection schemes in an atmosphere model. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_convective_snowfall_amount.json b/data_descriptors/standard_name/lwe_thickness_of_convective_snowfall_amount.json index bf20c650c..2a640c0f3 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_convective_snowfall_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_convective_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_convective_snowfall_amount", + "id": "lwe_thickness_of_convective_snowfall_amount", "type": "standard_name", "name": "lwe_thickness_of_convective_snowfall_amount", "description": "\"lwe\" means liquid water equivalent. \"Amount\" means mass per unit area. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_frozen_water_content_of_soil_layer.json b/data_descriptors/standard_name/lwe_thickness_of_frozen_water_content_of_soil_layer.json index 97603c904..781f2d2fd 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_frozen_water_content_of_soil_layer.json +++ b/data_descriptors/standard_name/lwe_thickness_of_frozen_water_content_of_soil_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_frozen_water_content_of_soil_layer", + "id": "lwe_thickness_of_frozen_water_content_of_soil_layer", "type": "standard_name", "name": "lwe_thickness_of_frozen_water_content_of_soil_layer", "description": "\"frozen_water\" means ice. \"lwe\" means liquid water equivalent. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).", diff --git a/data_descriptors/standard_name/lwe_thickness_of_moisture_content_of_soil_layer.json b/data_descriptors/standard_name/lwe_thickness_of_moisture_content_of_soil_layer.json index ac55feb10..2f448a6cf 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_moisture_content_of_soil_layer.json +++ b/data_descriptors/standard_name/lwe_thickness_of_moisture_content_of_soil_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_moisture_content_of_soil_layer", + "id": "lwe_thickness_of_moisture_content_of_soil_layer", "type": "standard_name", "name": "lwe_thickness_of_moisture_content_of_soil_layer", "description": "\"lwe\" means liquid water equivalent. \"moisture\" means water in all phases contained in soil. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).", diff --git a/data_descriptors/standard_name/lwe_thickness_of_precipitation_amount.json b/data_descriptors/standard_name/lwe_thickness_of_precipitation_amount.json index 55ea3b092..ff52f18a5 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_precipitation_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_precipitation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_precipitation_amount", + "id": "lwe_thickness_of_precipitation_amount", "type": "standard_name", "name": "lwe_thickness_of_precipitation_amount", "description": "The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_snowfall_amount.json b/data_descriptors/standard_name/lwe_thickness_of_snowfall_amount.json index fcf105658..bff22dfe3 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_snowfall_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_snowfall_amount", + "id": "lwe_thickness_of_snowfall_amount", "type": "standard_name", "name": "lwe_thickness_of_snowfall_amount", "description": "\"lwe\" means liquid water equivalent. \"Amount\" means mass per unit area. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_soil_moisture_content.json b/data_descriptors/standard_name/lwe_thickness_of_soil_moisture_content.json index b0ef42877..4f6e8ec28 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_soil_moisture_content.json +++ b/data_descriptors/standard_name/lwe_thickness_of_soil_moisture_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_soil_moisture_content", + "id": "lwe_thickness_of_soil_moisture_content", "type": "standard_name", "name": "lwe_thickness_of_soil_moisture_content", "description": "\"lwe\" means liquid water equivalent. \"moisture\" means water in all phases contained in soil. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_stratiform_precipitation_amount.json b/data_descriptors/standard_name/lwe_thickness_of_stratiform_precipitation_amount.json index 9e1a1f8e1..14759b9e6 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_stratiform_precipitation_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_stratiform_precipitation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_stratiform_precipitation_amount", + "id": "lwe_thickness_of_stratiform_precipitation_amount", "type": "standard_name", "name": "lwe_thickness_of_stratiform_precipitation_amount", "description": "The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_stratiform_snowfall_amount.json b/data_descriptors/standard_name/lwe_thickness_of_stratiform_snowfall_amount.json index df7c78235..266e16880 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_stratiform_snowfall_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_stratiform_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_stratiform_snowfall_amount", + "id": "lwe_thickness_of_stratiform_snowfall_amount", "type": "standard_name", "name": "lwe_thickness_of_stratiform_snowfall_amount", "description": "\"Amount\" means mass per unit area. \"lwe\" means liquid water equivalent. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_surface_snow_amount.json b/data_descriptors/standard_name/lwe_thickness_of_surface_snow_amount.json index d8809db5c..3600183ab 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_surface_snow_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_surface_snow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_surface_snow_amount", + "id": "lwe_thickness_of_surface_snow_amount", "type": "standard_name", "name": "lwe_thickness_of_surface_snow_amount", "description": "The abbreviation \"lwe\" means liquid water equivalent. \"Amount\" means mass per unit area. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/lwe_thickness_of_water_evaporation_amount.json b/data_descriptors/standard_name/lwe_thickness_of_water_evaporation_amount.json index 1b8e0ac05..1abb2c684 100644 --- a/data_descriptors/standard_name/lwe_thickness_of_water_evaporation_amount.json +++ b/data_descriptors/standard_name/lwe_thickness_of_water_evaporation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_thickness_of_water_evaporation_amount", + "id": "lwe_thickness_of_water_evaporation_amount", "type": "standard_name", "name": "lwe_thickness_of_water_evaporation_amount", "description": "\"lwe\" means liquid water equivalent. \"Amount\" means mass per unit area. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".)", diff --git a/data_descriptors/standard_name/lwe_water_evaporation_rate.json b/data_descriptors/standard_name/lwe_water_evaporation_rate.json index a6169fb21..411662261 100644 --- a/data_descriptors/standard_name/lwe_water_evaporation_rate.json +++ b/data_descriptors/standard_name/lwe_water_evaporation_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/lwe_water_evaporation_rate", + "id": "lwe_water_evaporation_rate", "type": "standard_name", "name": "lwe_water_evaporation_rate", "description": "\"lwe\" means liquid water equivalent. \"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".)", diff --git a/data_descriptors/standard_name/magnitude_of_air_velocity_relative_to_sea_water.json b/data_descriptors/standard_name/magnitude_of_air_velocity_relative_to_sea_water.json index 804d460bd..f328a5836 100644 --- a/data_descriptors/standard_name/magnitude_of_air_velocity_relative_to_sea_water.json +++ b/data_descriptors/standard_name/magnitude_of_air_velocity_relative_to_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_air_velocity_relative_to_sea_water", + "id": "magnitude_of_air_velocity_relative_to_sea_water", "type": "standard_name", "name": "magnitude_of_air_velocity_relative_to_sea_water", "description": "The quantity with standard name magnitude_of_air_velocity_relative_to_sea_water is the speed of the motion of the air relative to the near-surface current, usually derived from vectors. The components of the relative velocity vector have standard names eastward_air_velocity_relative_to_sea_water and northward_air_velocity_relative_to_sea_water. A vertical coordinate variable or scalar coordinate variable with standard name \"depth\" should be used to indicate the depth of sea water velocity used in the calculation. Similarly, a vertical coordinate variable or scalar coordinate with standard name \"height\" should be used to indicate the height of the the wind component.", diff --git a/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_model_level_number.json b/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_model_level_number.json index 3deec3de6..ce4045ab8 100644 --- a/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_model_level_number.json +++ b/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_model_level_number.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_derivative_of_position_wrt_model_level_number", + "id": "magnitude_of_derivative_of_position_wrt_model_level_number", "type": "standard_name", "name": "magnitude_of_derivative_of_position_wrt_model_level_number", "description": "The quantity with standard name magnitude_of_derivative_of_position_wrt_model_level_number (known in differential geometry as a \"scale factor\") is | (dr/dk)ij|, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It is a measure of the gridblock spacing in the z-direction.", diff --git a/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_x_coordinate_index.json b/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_x_coordinate_index.json index 93d42e4bc..adde36df8 100644 --- a/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_x_coordinate_index.json +++ b/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_x_coordinate_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_derivative_of_position_wrt_x_coordinate_index", + "id": "magnitude_of_derivative_of_position_wrt_x_coordinate_index", "type": "standard_name", "name": "magnitude_of_derivative_of_position_wrt_x_coordinate_index", "description": "The quantity with standard name magnitude_of_derivative_of_position_wrt_x_coordinate_index (known in differential geometry as a \"scale factor\") is | (dr/di)jk|, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It is a measure of the gridblock spacing in the x-direction.", diff --git a/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_y_coordinate_index.json b/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_y_coordinate_index.json index 9e9c441a4..0c30e59df 100644 --- a/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_y_coordinate_index.json +++ b/data_descriptors/standard_name/magnitude_of_derivative_of_position_wrt_y_coordinate_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_derivative_of_position_wrt_y_coordinate_index", + "id": "magnitude_of_derivative_of_position_wrt_y_coordinate_index", "type": "standard_name", "name": "magnitude_of_derivative_of_position_wrt_y_coordinate_index", "description": "The quantity with standard name magnitude_of_derivative_of_position_wrt_y_coordinate_index (known in differential geometry as a \"scale factor\") is | (dr/dj)ik|, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It is a measure of the gridblock spacing in the y-direction.", diff --git a/data_descriptors/standard_name/magnitude_of_heat_flux_in_sea_water_due_to_advection.json b/data_descriptors/standard_name/magnitude_of_heat_flux_in_sea_water_due_to_advection.json index a2956a523..de7c3a44b 100644 --- a/data_descriptors/standard_name/magnitude_of_heat_flux_in_sea_water_due_to_advection.json +++ b/data_descriptors/standard_name/magnitude_of_heat_flux_in_sea_water_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_heat_flux_in_sea_water_due_to_advection", + "id": "magnitude_of_heat_flux_in_sea_water_due_to_advection", "type": "standard_name", "name": "magnitude_of_heat_flux_in_sea_water_due_to_advection", "description": "\"magnitude_of_X\" means magnitude of a vector X. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/magnitude_of_sea_ice_displacement.json b/data_descriptors/standard_name/magnitude_of_sea_ice_displacement.json index 4214f3b2c..60cc1a0a4 100644 --- a/data_descriptors/standard_name/magnitude_of_sea_ice_displacement.json +++ b/data_descriptors/standard_name/magnitude_of_sea_ice_displacement.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_sea_ice_displacement", + "id": "magnitude_of_sea_ice_displacement", "type": "standard_name", "name": "magnitude_of_sea_ice_displacement", "description": "The phrase \"magnitude_of_X\" means magnitude of a vector X. \"Displacement\" means the change in geospatial position of an object that has moved over time. If possible, the time interval over which the motion took place should be specified using a bounds variable for the time coordinate variable. A displacement can be represented as a vector. Such a vector should however not be interpreted as describing a rectilinear, constant speed motion but merely as an indication that the start point of the vector is found at the tip of the vector after the time interval associated with the displacement variable. A displacement does not prescribe a trajectory. Sea ice displacement can be defined as a two-dimensional vector, with no vertical component. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/magnitude_of_surface_downward_stress.json b/data_descriptors/standard_name/magnitude_of_surface_downward_stress.json index 82a7ed737..7e88792a6 100644 --- a/data_descriptors/standard_name/magnitude_of_surface_downward_stress.json +++ b/data_descriptors/standard_name/magnitude_of_surface_downward_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/magnitude_of_surface_downward_stress", + "id": "magnitude_of_surface_downward_stress", "type": "standard_name", "name": "magnitude_of_surface_downward_stress", "description": "The phrase \"magnitude_of_X\" means magnitude of a vector X. The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward).", diff --git a/data_descriptors/standard_name/mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water.json index 4ac7dd516..12d827e44 100644 --- a/data_descriptors/standard_name/mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water", + "id": "mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_19_butanoyloxyfucoxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of 19\u2019-butanoyloxyfucoxanthin is C46H64O8. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/BUTAXXXX/1/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water.json index 564862fee..b43ce147c 100644 --- a/data_descriptors/standard_name/mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water", + "id": "mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_19_hexanoyloxyfucoxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of 19'-hexanoyloxyfucoxanthin is C48H68O8. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/HEXAXXXX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air.json index 92cd86c8b..0435d4181 100644 --- a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_absorption_equivalent_black_carbon_of_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The absorption equivalent black carbon mass concentration is obtained by conversion from the particle light absorption coefficient with a suitable mass absorption cross-section. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air.json index 10534cdc5..96e1b29e5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_absorption_equivalent_black_carbon_of_pm10_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The absorption equivalent black carbon mass concentration is obtained by conversion from the particle light absorption coefficient with a suitable mass absorption cross-section. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air.json index ac71199de..7ec194755 100644 --- a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_absorption_equivalent_black_carbon_of_pm1_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. The absorption equivalent black carbon mass concentration is obtained by conversion from the particle light absorption coefficient with a suitable mass absorption cross-section. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air.json index c2525ff0f..7fe8d4a35 100644 --- a/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_absorption_equivalent_black_carbon_of_pm2p5_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The absorption equivalent black carbon mass concentration is obtained by conversion from the particle light absorption coefficient with a suitable mass absorption cross-section. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_acetic_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_acetic_acid_in_air.json index 0694095e9..72fe2a5ab 100644 --- a/data_descriptors/standard_name/mass_concentration_of_acetic_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_acetic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_acetic_acid_in_air", + "id": "mass_concentration_of_acetic_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_acetic_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/mass_concentration_of_aceto_nitrile_in_air.json b/data_descriptors/standard_name/mass_concentration_of_aceto_nitrile_in_air.json index e4fc8223a..ad4f755e6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_aceto_nitrile_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_aceto_nitrile_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_aceto_nitrile_in_air", + "id": "mass_concentration_of_aceto_nitrile_in_air", "type": "standard_name", "name": "mass_concentration_of_aceto_nitrile_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/mass_concentration_of_adenosine_triphosphate_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_adenosine_triphosphate_in_sea_water.json index 5e357232a..6b691bc6b 100644 --- a/data_descriptors/standard_name/mass_concentration_of_adenosine_triphosphate_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_adenosine_triphosphate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_adenosine_triphosphate_in_sea_water", + "id": "mass_concentration_of_adenosine_triphosphate_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_adenosine_triphosphate_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/ATPXZZDZ/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_alkanes_in_air.json b/data_descriptors/standard_name/mass_concentration_of_alkanes_in_air.json index dcc5ecea2..b8709f8a9 100644 --- a/data_descriptors/standard_name/mass_concentration_of_alkanes_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_alkanes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_alkanes_in_air", + "id": "mass_concentration_of_alkanes_in_air", "type": "standard_name", "name": "mass_concentration_of_alkanes_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Alkanes are saturated hydrocarbons, i.e. they do not contain any chemical double bonds. Alkanes contain only hydrogen and carbon combined in the general proportions C(n)H(2n+2); \"alkanes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkane species, e.g., methane and ethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_alkenes_in_air.json b/data_descriptors/standard_name/mass_concentration_of_alkenes_in_air.json index ae6a88f17..a38e63a2a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_alkenes_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_alkenes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_alkenes_in_air", + "id": "mass_concentration_of_alkenes_in_air", "type": "standard_name", "name": "mass_concentration_of_alkenes_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Alkenes are unsaturated hydrocarbons as they contain chemical double bonds between adjacent carbon atoms. Alkenes contain only hydrogen and carbon combined in the general proportions C(n)H(2n); \"alkenes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkene species, e.g., ethene and propene.", diff --git a/data_descriptors/standard_name/mass_concentration_of_alpha_carotene_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_alpha_carotene_in_sea_water.json index a204c3f7b..c9d84ec82 100644 --- a/data_descriptors/standard_name/mass_concentration_of_alpha_carotene_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_alpha_carotene_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_alpha_carotene_in_sea_water", + "id": "mass_concentration_of_alpha_carotene_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_alpha_carotene_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of alpha-carotene is C40H56. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/BECAXXP1/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_alpha_hexachlorocyclohexane_in_air.json b/data_descriptors/standard_name/mass_concentration_of_alpha_hexachlorocyclohexane_in_air.json index 65d0dc331..c733b0e10 100644 --- a/data_descriptors/standard_name/mass_concentration_of_alpha_hexachlorocyclohexane_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_alpha_hexachlorocyclohexane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_alpha_hexachlorocyclohexane_in_air", + "id": "mass_concentration_of_alpha_hexachlorocyclohexane_in_air", "type": "standard_name", "name": "mass_concentration_of_alpha_hexachlorocyclohexane_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for alpha_hexachlorocyclohexane is C6H6Cl6.", diff --git a/data_descriptors/standard_name/mass_concentration_of_alpha_pinene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_alpha_pinene_in_air.json index 829acd2f2..598ea2d9f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_alpha_pinene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_alpha_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_alpha_pinene_in_air", + "id": "mass_concentration_of_alpha_pinene_in_air", "type": "standard_name", "name": "mass_concentration_of_alpha_pinene_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/mass_concentration_of_aluminium_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_aluminium_in_sea_floor_sediment.json index cb39baf57..9b7e2d11b 100644 --- a/data_descriptors/standard_name/mass_concentration_of_aluminium_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_aluminium_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_aluminium_in_sea_floor_sediment", + "id": "mass_concentration_of_aluminium_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_aluminium_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Aluminium means aluminium in all chemical forms, commonly referred to as \"total aluminium\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ammonia_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ammonia_in_air.json index 0da6c6b2c..14ea5a405 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ammonia_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ammonia_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ammonia_in_air", + "id": "mass_concentration_of_ammonia_in_air", "type": "standard_name", "name": "mass_concentration_of_ammonia_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ammonium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ammonium_dry_aerosol_particles_in_air.json index b5f0cf4c3..4140d8a27 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ammonium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ammonium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ammonium_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_ammonium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_ammonium_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for ammonium is NH4.", diff --git a/data_descriptors/standard_name/mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json index cdc6e5947..60c65b589 100644 --- a/data_descriptors/standard_name/mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/mass_concentration_of_aromatic_compounds_in_air.json b/data_descriptors/standard_name/mass_concentration_of_aromatic_compounds_in_air.json index a7c9d9e5b..4000b929c 100644 --- a/data_descriptors/standard_name/mass_concentration_of_aromatic_compounds_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_aromatic_compounds_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_aromatic_compounds_in_air", + "id": "mass_concentration_of_aromatic_compounds_in_air", "type": "standard_name", "name": "mass_concentration_of_aromatic_compounds_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Aromatic compounds in organic chemistry are compounds that contain at least one benzene ring of six carbon atoms joined by alternating single and double covalent bonds. The simplest aromatic compound is benzene itself. In standard names \"aromatic_compounds\" is the term used to describe the group of aromatic chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual aromatic species, e.g. benzene and xylene.", diff --git a/data_descriptors/standard_name/mass_concentration_of_arsenic_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_arsenic_in_sea_floor_sediment.json index 6412b5d8f..cca14d3ff 100644 --- a/data_descriptors/standard_name/mass_concentration_of_arsenic_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_arsenic_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_arsenic_in_sea_floor_sediment", + "id": "mass_concentration_of_arsenic_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_arsenic_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Arsenic means arsenic in all chemical forms, commonly referred to as \"total arsenic\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_atomic_bromine_in_air.json b/data_descriptors/standard_name/mass_concentration_of_atomic_bromine_in_air.json index 139174283..9a1a5bc6d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_atomic_bromine_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_atomic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_atomic_bromine_in_air", + "id": "mass_concentration_of_atomic_bromine_in_air", "type": "standard_name", "name": "mass_concentration_of_atomic_bromine_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic bromine is Br.", diff --git a/data_descriptors/standard_name/mass_concentration_of_atomic_chlorine_in_air.json b/data_descriptors/standard_name/mass_concentration_of_atomic_chlorine_in_air.json index c11f07aa9..c277baa95 100644 --- a/data_descriptors/standard_name/mass_concentration_of_atomic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_atomic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_atomic_chlorine_in_air", + "id": "mass_concentration_of_atomic_chlorine_in_air", "type": "standard_name", "name": "mass_concentration_of_atomic_chlorine_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/mass_concentration_of_atomic_nitrogen_in_air.json b/data_descriptors/standard_name/mass_concentration_of_atomic_nitrogen_in_air.json index 32d01e4a7..455063d29 100644 --- a/data_descriptors/standard_name/mass_concentration_of_atomic_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_atomic_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_atomic_nitrogen_in_air", + "id": "mass_concentration_of_atomic_nitrogen_in_air", "type": "standard_name", "name": "mass_concentration_of_atomic_nitrogen_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/mass_concentration_of_benzene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_benzene_in_air.json index ff0c60a8b..aa8564265 100644 --- a/data_descriptors/standard_name/mass_concentration_of_benzene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_benzene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_benzene_in_air", + "id": "mass_concentration_of_benzene_in_air", "type": "standard_name", "name": "mass_concentration_of_benzene_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_beta_carotene_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_beta_carotene_in_sea_water.json index 65277070b..7c330dcd0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_beta_carotene_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_beta_carotene_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_beta_carotene_in_sea_water", + "id": "mass_concentration_of_beta_carotene_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_beta_carotene_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of beta-carotene is C40H56. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/BBCAXXP1/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_beta_pinene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_beta_pinene_in_air.json index 451cc75fa..67db36757 100644 --- a/data_descriptors/standard_name/mass_concentration_of_beta_pinene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_beta_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_beta_pinene_in_air", + "id": "mass_concentration_of_beta_pinene_in_air", "type": "standard_name", "name": "mass_concentration_of_beta_pinene_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json index 48dc27af1..8cce79204 100644 --- a/data_descriptors/standard_name/mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes.", diff --git a/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json index 747102ba3..63ad23636 100644 --- a/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Mass concentration of biota expressed as carbon is also referred to as \"carbon biomass\". \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water.json index 94ab3f1ca..007a97b32 100644 --- a/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_biological_taxon_expressed_as_chlorophyll_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms.", diff --git a/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json index 841a91495..dfc319cda 100644 --- a/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water", + "id": "mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Mass concentration of biota expressed as nitrogen is also referred to as \"nitrogen biomass\". \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air.json index 426e5f011..1d4ee3f82 100644 --- a/data_descriptors/standard_name/mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_biomass_burning_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_concentration_of_bromine_chloride_in_air.json b/data_descriptors/standard_name/mass_concentration_of_bromine_chloride_in_air.json index 3a9978e9f..db7f9387d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_bromine_chloride_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_bromine_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_bromine_chloride_in_air", + "id": "mass_concentration_of_bromine_chloride_in_air", "type": "standard_name", "name": "mass_concentration_of_bromine_chloride_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/mass_concentration_of_bromine_monoxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_bromine_monoxide_in_air.json index bb14f9e80..9ac91d346 100644 --- a/data_descriptors/standard_name/mass_concentration_of_bromine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_bromine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_bromine_monoxide_in_air", + "id": "mass_concentration_of_bromine_monoxide_in_air", "type": "standard_name", "name": "mass_concentration_of_bromine_monoxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/mass_concentration_of_bromine_nitrate_in_air.json b/data_descriptors/standard_name/mass_concentration_of_bromine_nitrate_in_air.json index 45a5b3d5c..b694ea070 100644 --- a/data_descriptors/standard_name/mass_concentration_of_bromine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_bromine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_bromine_nitrate_in_air", + "id": "mass_concentration_of_bromine_nitrate_in_air", "type": "standard_name", "name": "mass_concentration_of_bromine_nitrate_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for bromine nitrate is BrONO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_brox_expressed_as_bromine_in_air.json b/data_descriptors/standard_name/mass_concentration_of_brox_expressed_as_bromine_in_air.json index d4b366d99..8f9777e3e 100644 --- a/data_descriptors/standard_name/mass_concentration_of_brox_expressed_as_bromine_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_brox_expressed_as_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_brox_expressed_as_bromine_in_air", + "id": "mass_concentration_of_brox_expressed_as_bromine_in_air", "type": "standard_name", "name": "mass_concentration_of_brox_expressed_as_bromine_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_butane_in_air.json b/data_descriptors/standard_name/mass_concentration_of_butane_in_air.json index f81c49ce9..c4f816f2f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_butane_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_butane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_butane_in_air", + "id": "mass_concentration_of_butane_in_air", "type": "standard_name", "name": "mass_concentration_of_butane_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cadmium_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_cadmium_in_sea_floor_sediment.json index 671a38297..e6574a5dd 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cadmium_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_cadmium_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cadmium_in_sea_floor_sediment", + "id": "mass_concentration_of_cadmium_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_cadmium_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Cadmium means cadmium in all chemical forms, commonly referred to as \"total cadmium\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json index 94b845c52..a6990de9f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. \"Calcareous phytoplankton\" are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_dioxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_dioxide_in_air.json index b96d5d4b9..59b73ef71 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_dioxide_in_air", + "id": "mass_concentration_of_carbon_dioxide_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_dioxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_in_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_in_dry_aerosol_particles_in_air.json index 5819f055a..40f56e710 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_in_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_in_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_in_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_carbon_in_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_in_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"carbon\" is the total sum of elemental, organic, and inorganic carbon. In measurements of carbonaceous aerosols, inorganic carbon is neglected and its mass is assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air.json index 69efd7781..f1fe5c62a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_in_pm10_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. Chemically, \"carbon\" is the total sum of elemental, organic, and inorganic carbon. In measurements of carbonaceous aerosols, inorganic carbon is neglected and its mass is assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air.json index a984bd786..c172f7b60 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_in_pm1_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. Chemically, \"carbon\" is the total sum of elemental, organic, and inorganic carbon. In measurements of carbonaceous aerosols, inorganic carbon is neglected and its mass is assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air.json index 000a9f815..fb49c6a17 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_in_pm2p5_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. Chemically, \"carbon\" is the total sum of elemental, organic, and inorganic carbon. In measurements of carbonaceous aerosols, inorganic carbon is neglected and its mass is assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_monoxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_monoxide_in_air.json index 10eb9114d..87e50edd5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_monoxide_in_air", + "id": "mass_concentration_of_carbon_monoxide_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_monoxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carbon_tetrachloride_in_air.json b/data_descriptors/standard_name/mass_concentration_of_carbon_tetrachloride_in_air.json index 6807f8fdd..6957dd524 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carbon_tetrachloride_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_carbon_tetrachloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carbon_tetrachloride_in_air", + "id": "mass_concentration_of_carbon_tetrachloride_in_air", "type": "standard_name", "name": "mass_concentration_of_carbon_tetrachloride_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_carotene_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_carotene_in_sea_water.json index 2a680ade6..849d97411 100644 --- a/data_descriptors/standard_name/mass_concentration_of_carotene_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_carotene_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_carotene_in_sea_water", + "id": "mass_concentration_of_carotene_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_carotene_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Carotene\" refers to the sum of all forms of the carotenoid pigment carotene. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/CAROXXXX/1/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cfc113_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cfc113_in_air.json index 76b78d43b..ce82b95a7 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cfc113_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cfc113_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cfc113_in_air", + "id": "mass_concentration_of_cfc113_in_air", "type": "standard_name", "name": "mass_concentration_of_cfc113_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cfc113a_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cfc113a_in_air.json index 249906f8b..59ca68da4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cfc113a_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cfc113a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cfc113a_in_air", + "id": "mass_concentration_of_cfc113a_in_air", "type": "standard_name", "name": "mass_concentration_of_cfc113a_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cfc114_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cfc114_in_air.json index d15ffdcfa..140875458 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cfc114_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cfc114_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cfc114_in_air", + "id": "mass_concentration_of_cfc114_in_air", "type": "standard_name", "name": "mass_concentration_of_cfc114_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cfc115_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cfc115_in_air.json index f4262a4c4..a8f231d08 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cfc115_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cfc115_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cfc115_in_air", + "id": "mass_concentration_of_cfc115_in_air", "type": "standard_name", "name": "mass_concentration_of_cfc115_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cfc11_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cfc11_in_air.json index 1ee9e114f..ce2a1c60a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cfc11_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cfc11_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cfc11_in_air", + "id": "mass_concentration_of_cfc11_in_air", "type": "standard_name", "name": "mass_concentration_of_cfc11_in_air", "description": "Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cfc12_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cfc12_in_air.json index 7bd987457..9e8249173 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cfc12_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cfc12_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cfc12_in_air", + "id": "mass_concentration_of_cfc12_in_air", "type": "standard_name", "name": "mass_concentration_of_cfc12_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorine_dioxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_chlorine_dioxide_in_air.json index 205c21019..7d1ae5ee6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorine_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorine_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorine_dioxide_in_air", + "id": "mass_concentration_of_chlorine_dioxide_in_air", "type": "standard_name", "name": "mass_concentration_of_chlorine_dioxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorine_monoxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_chlorine_monoxide_in_air.json index 015142d1c..249b0a11e 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorine_monoxide_in_air", + "id": "mass_concentration_of_chlorine_monoxide_in_air", "type": "standard_name", "name": "mass_concentration_of_chlorine_monoxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorine_nitrate_in_air.json b/data_descriptors/standard_name/mass_concentration_of_chlorine_nitrate_in_air.json index 719907fa9..64da6bd16 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorine_nitrate_in_air", + "id": "mass_concentration_of_chlorine_nitrate_in_air", "type": "standard_name", "name": "mass_concentration_of_chlorine_nitrate_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_floor_sediment.json index edae087ba..28d34cd52 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_a_in_sea_floor_sediment", + "id": "mass_concentration_of_chlorophyll_a_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_a_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Chlorophyll-a is the most commonly occurring form of natural chlorophyll. The chemical formula of chlorophyll-a is C55H72O5N4Mg. \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_ice.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_ice.json index 5b1e2a807..820370dce 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_ice.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_a_in_sea_ice", + "id": "mass_concentration_of_chlorophyll_a_in_sea_ice", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_a_in_sea_ice", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Chlorophyll-a is the most commonly occurring form of natural chlorophyll. The chemical formula of chlorophyll-a is C55H72O5N4Mg. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_water.json index 3eb2eb1ae..4fca66ecb 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_a_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_a_in_sea_water", + "id": "mass_concentration_of_chlorophyll_a_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_a_in_sea_water", "description": "'Mass concentration' means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Chlorophyll-a is the most commonly occurring form of natural chlorophyll. The chemical formula of chlorophyll-a is C55H72O5N4Mg.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_b_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_b_in_sea_water.json index 68212bed2..ae13077c8 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_b_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_b_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_b_in_sea_water", + "id": "mass_concentration_of_chlorophyll_b_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_b_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/CHLBXXPX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water.json index 1001dc334..0c9c787d6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water", + "id": "mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_c1_and_chlorophyll_c2_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Chlorophyll c1c2 (sometimes written c1-c2 or c1+c2) means the sum of chlorophyll c1 and chlorophyll c2. The chemical formula of chlorophyll c1 is C35H30MgN4O5, and chlorophyll c2 is C35H28MgN4O5. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/CHLC12PX/3/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c3_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c3_in_sea_water.json index 340c76560..03b2b64b4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c3_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c3_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_c3_in_sea_water", + "id": "mass_concentration_of_chlorophyll_c3_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_c3_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. The chemical formula of chlorophyll c3 is C36H44MgN4O7. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/CHLC03PX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c4_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c4_in_sea_water.json index 965b5a7ad..a63813630 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c4_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c4_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_c4_in_sea_water", + "id": "mass_concentration_of_chlorophyll_c4_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_c4_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c_in_sea_water.json index dcce87dcc..5b4d6068b 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_c_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_c_in_sea_water", + "id": "mass_concentration_of_chlorophyll_c_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_c_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Chlorophyll-c means chlorophyll c1+c2+c3. The chemical formula of chlorophyll c1 is C35H30MgN4O5, and chlorophyll c2 is C35H28MgN4O5. The chemical formula of chlorophyll c3 is C36H44MgN4O7.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_in_sea_water.json index a73c38f7c..c13dae3af 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyll_in_sea_water", + "id": "mass_concentration_of_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chlorophyllide_a_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_chlorophyllide_a_in_sea_water.json index 83c8fd662..d09a11943 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chlorophyllide_a_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_chlorophyllide_a_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chlorophyllide_a_in_sea_water", + "id": "mass_concentration_of_chlorophyllide_a_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_chlorophyllide_a_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of chlorophyllide-a is C35H34MgN4O5.", diff --git a/data_descriptors/standard_name/mass_concentration_of_chromium_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_chromium_in_sea_floor_sediment.json index b20ddc808..06406c102 100644 --- a/data_descriptors/standard_name/mass_concentration_of_chromium_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_chromium_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_chromium_in_sea_floor_sediment", + "id": "mass_concentration_of_chromium_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_chromium_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Chromium means chromium in all chemical forms, commonly referred to as \"total chromium\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/mass_concentration_of_cloud_liquid_water_in_air.json index 9c0f54f86..23aeaef9e 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cloud_liquid_water_in_air", + "id": "mass_concentration_of_cloud_liquid_water_in_air", "type": "standard_name", "name": "mass_concentration_of_cloud_liquid_water_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/mass_concentration_of_clox_expressed_as_chlorine_in_air.json b/data_descriptors/standard_name/mass_concentration_of_clox_expressed_as_chlorine_in_air.json index 52d49df1e..680fccb16 100644 --- a/data_descriptors/standard_name/mass_concentration_of_clox_expressed_as_chlorine_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_clox_expressed_as_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_clox_expressed_as_chlorine_in_air", + "id": "mass_concentration_of_clox_expressed_as_chlorine_in_air", "type": "standard_name", "name": "mass_concentration_of_clox_expressed_as_chlorine_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json index 633d8c459..80a29c0ff 100644 --- a/data_descriptors/standard_name/mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. Coarse mode aerosol particles have a diameter of more than 1 micrometer.", diff --git a/data_descriptors/standard_name/mass_concentration_of_cobalt_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_cobalt_in_sea_floor_sediment.json index 280507341..5a7272121 100644 --- a/data_descriptors/standard_name/mass_concentration_of_cobalt_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_cobalt_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_cobalt_in_sea_floor_sediment", + "id": "mass_concentration_of_cobalt_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_cobalt_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as \"nox_expressed_as_nitrogen\". Cobalt means cobalt in all chemical forms, commonly referred to as \"total cobalt\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_condensed_water_in_soil.json b/data_descriptors/standard_name/mass_concentration_of_condensed_water_in_soil.json index 566a4027b..439d03806 100644 --- a/data_descriptors/standard_name/mass_concentration_of_condensed_water_in_soil.json +++ b/data_descriptors/standard_name/mass_concentration_of_condensed_water_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_condensed_water_in_soil", + "id": "mass_concentration_of_condensed_water_in_soil", "type": "standard_name", "name": "mass_concentration_of_condensed_water_in_soil", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. Condensed water means liquid and ice.", diff --git a/data_descriptors/standard_name/mass_concentration_of_copper_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_copper_in_sea_floor_sediment.json index dfec76bf2..b9b8e75b5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_copper_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_copper_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_copper_in_sea_floor_sediment", + "id": "mass_concentration_of_copper_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_copper_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Copper means copper in all chemical forms, commonly referred to as \"total copper\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_diadinoxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_diadinoxanthin_in_sea_water.json index 5d5d942af..30bc8f6a7 100644 --- a/data_descriptors/standard_name/mass_concentration_of_diadinoxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_diadinoxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_diadinoxanthin_in_sea_water", + "id": "mass_concentration_of_diadinoxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_diadinoxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of diadinoxanthin is C40H54O3. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/DIADXXXX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json index f8ddc4e97..c48e29fc1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Diatoms are single-celled phytoplankton with an external skeleton made of silica. Phytoplankton are a algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water.json index 10e7e2bf4..e9460803b 100644 --- a/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Diatoms are single-celled phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json index 593881357..474704c2c 100644 --- a/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water", + "id": "mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Diatoms are single-celled phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json index 825deef3e..b713c38be 100644 --- a/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water.json index 22667f8f3..09ec7fd7d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_diazotrophic_phytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/mass_concentration_of_dichlorine_peroxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_dichlorine_peroxide_in_air.json index dc7af9975..f3c8e37c8 100644 --- a/data_descriptors/standard_name/mass_concentration_of_dichlorine_peroxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_dichlorine_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_dichlorine_peroxide_in_air", + "id": "mass_concentration_of_dichlorine_peroxide_in_air", "type": "standard_name", "name": "mass_concentration_of_dichlorine_peroxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_dimethyl_sulfide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_dimethyl_sulfide_in_air.json index 5a175dd24..84cab3a99 100644 --- a/data_descriptors/standard_name/mass_concentration_of_dimethyl_sulfide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_dimethyl_sulfide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_dimethyl_sulfide_in_air", + "id": "mass_concentration_of_dimethyl_sulfide_in_air", "type": "standard_name", "name": "mass_concentration_of_dimethyl_sulfide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/mass_concentration_of_dinitrogen_pentoxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_dinitrogen_pentoxide_in_air.json index 61abab8eb..accf25e0f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_dinitrogen_pentoxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_dinitrogen_pentoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_dinitrogen_pentoxide_in_air", + "id": "mass_concentration_of_dinitrogen_pentoxide_in_air", "type": "standard_name", "name": "mass_concentration_of_dinitrogen_pentoxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/mass_concentration_of_divinyl_chlorophyll_a_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_divinyl_chlorophyll_a_in_sea_water.json index d28c76d03..0d847fbf1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_divinyl_chlorophyll_a_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_divinyl_chlorophyll_a_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_divinyl_chlorophyll_a_in_sea_water", + "id": "mass_concentration_of_divinyl_chlorophyll_a_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_divinyl_chlorophyll_a_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/mass_concentration_of_drizzle_in_air.json b/data_descriptors/standard_name/mass_concentration_of_drizzle_in_air.json index dd41851c3..6b28d6dd8 100644 --- a/data_descriptors/standard_name/mass_concentration_of_drizzle_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_drizzle_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_drizzle_in_air", + "id": "mass_concentration_of_drizzle_in_air", "type": "standard_name", "name": "mass_concentration_of_drizzle_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Drizzle\" means drops of water falling through the atmosphere that have a diameter typically in the range 0.2-0.5 mm.", diff --git a/data_descriptors/standard_name/mass_concentration_of_dust_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_dust_dry_aerosol_particles_in_air.json index ba50dd35e..6d865e1f0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_dust_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_dust_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_dust_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_dust_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_dust_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air.json index b58da9efb..ea2967343 100644 --- a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air.json index adb016b94..a9ceb6db2 100644 --- a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_elemental_carbon_in_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983). In measurements of carbonaceous aerosols, elemental carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air.json index f567599d7..24dbfd919 100644 --- a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_elemental_carbon_in_pm10_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983). In measurements of carbonaceous aerosols, elemental carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air.json index e1ce7ca67..2d7e96de1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_elemental_carbon_in_pm1_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983). In measurements of carbonaceous aerosols, elemental carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air.json index 90677a9e8..9ff6439ac 100644 --- a/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_elemental_carbon_in_pm2p5_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983). In measurements of carbonaceous aerosols, elemental carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ethane_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ethane_in_air.json index 05555bf66..d9e5e7067 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ethane_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ethane_in_air", + "id": "mass_concentration_of_ethane_in_air", "type": "standard_name", "name": "mass_concentration_of_ethane_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ethanol_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ethanol_in_air.json index 39f0e0eb7..03bd1f245 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ethanol_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ethanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ethanol_in_air", + "id": "mass_concentration_of_ethanol_in_air", "type": "standard_name", "name": "mass_concentration_of_ethanol_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ethene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ethene_in_air.json index 5dd094b53..dc9a72cca 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ethene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ethene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ethene_in_air", + "id": "mass_concentration_of_ethene_in_air", "type": "standard_name", "name": "mass_concentration_of_ethene_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ethyne_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ethyne_in_air.json index 757e68719..c8ac8b219 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ethyne_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ethyne_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ethyne_in_air", + "id": "mass_concentration_of_ethyne_in_air", "type": "standard_name", "name": "mass_concentration_of_ethyne_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water.json index a31090c3e..8bf075a1e 100644 --- a/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_flagellates_expressed_as_carbon_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Flagellates\" are a class of single celled organisms that use a flagellum (whip-like structure) for feeding and locomotion. Some flagellates can photosynthesize and others feed on bacteria, with a few flagellates capable of both.", diff --git a/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water.json index 8861878ad..336d35a99 100644 --- a/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water", + "id": "mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_flagellates_expressed_as_nitrogen_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Flagellates\" are a class of single celled organisms that use a flagellum (whip-like structure) for feeding and locomotion. Some flagellates can photosynthesize and others feed on bacteria, with a few flagellates capable of both.", diff --git a/data_descriptors/standard_name/mass_concentration_of_formaldehyde_in_air.json b/data_descriptors/standard_name/mass_concentration_of_formaldehyde_in_air.json index 9c0730370..81f16ca61 100644 --- a/data_descriptors/standard_name/mass_concentration_of_formaldehyde_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_formaldehyde_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_formaldehyde_in_air", + "id": "mass_concentration_of_formaldehyde_in_air", "type": "standard_name", "name": "mass_concentration_of_formaldehyde_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/mass_concentration_of_formic_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_formic_acid_in_air.json index 691e2019c..8fefc9a90 100644 --- a/data_descriptors/standard_name/mass_concentration_of_formic_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_formic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_formic_acid_in_air", + "id": "mass_concentration_of_formic_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_formic_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/mass_concentration_of_fucoxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_fucoxanthin_in_sea_water.json index f191ee81e..e293c2441 100644 --- a/data_descriptors/standard_name/mass_concentration_of_fucoxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_fucoxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_fucoxanthin_in_sea_water", + "id": "mass_concentration_of_fucoxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_fucoxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of fucoxanthin is C42H58O6. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/FUCXZZZZ/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_gaseous_divalent_mercury_in_air.json b/data_descriptors/standard_name/mass_concentration_of_gaseous_divalent_mercury_in_air.json index de9c2e28e..f120e3ff3 100644 --- a/data_descriptors/standard_name/mass_concentration_of_gaseous_divalent_mercury_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_gaseous_divalent_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_gaseous_divalent_mercury_in_air", + "id": "mass_concentration_of_gaseous_divalent_mercury_in_air", "type": "standard_name", "name": "mass_concentration_of_gaseous_divalent_mercury_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/mass_concentration_of_gaseous_elemental_mercury_in_air.json b/data_descriptors/standard_name/mass_concentration_of_gaseous_elemental_mercury_in_air.json index 4ca19cf7e..4165385d9 100644 --- a/data_descriptors/standard_name/mass_concentration_of_gaseous_elemental_mercury_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_gaseous_elemental_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_gaseous_elemental_mercury_in_air", + "id": "mass_concentration_of_gaseous_elemental_mercury_in_air", "type": "standard_name", "name": "mass_concentration_of_gaseous_elemental_mercury_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for mercury is Hg.", diff --git a/data_descriptors/standard_name/mass_concentration_of_halon1202_in_air.json b/data_descriptors/standard_name/mass_concentration_of_halon1202_in_air.json index cfcdf3482..23ef0b33b 100644 --- a/data_descriptors/standard_name/mass_concentration_of_halon1202_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_halon1202_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_halon1202_in_air", + "id": "mass_concentration_of_halon1202_in_air", "type": "standard_name", "name": "mass_concentration_of_halon1202_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_halon1211_in_air.json b/data_descriptors/standard_name/mass_concentration_of_halon1211_in_air.json index 321231419..21dbb41fb 100644 --- a/data_descriptors/standard_name/mass_concentration_of_halon1211_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_halon1211_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_halon1211_in_air", + "id": "mass_concentration_of_halon1211_in_air", "type": "standard_name", "name": "mass_concentration_of_halon1211_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_halon1301_in_air.json b/data_descriptors/standard_name/mass_concentration_of_halon1301_in_air.json index c10fb1c45..b5cf94ff3 100644 --- a/data_descriptors/standard_name/mass_concentration_of_halon1301_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_halon1301_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_halon1301_in_air", + "id": "mass_concentration_of_halon1301_in_air", "type": "standard_name", "name": "mass_concentration_of_halon1301_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_halon2402_in_air.json b/data_descriptors/standard_name/mass_concentration_of_halon2402_in_air.json index 101f5ad18..025ba84ce 100644 --- a/data_descriptors/standard_name/mass_concentration_of_halon2402_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_halon2402_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_halon2402_in_air", + "id": "mass_concentration_of_halon2402_in_air", "type": "standard_name", "name": "mass_concentration_of_halon2402_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hcc140a_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hcc140a_in_air.json index 4863a7d7e..95ec79975 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hcc140a_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hcc140a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hcc140a_in_air", + "id": "mass_concentration_of_hcc140a_in_air", "type": "standard_name", "name": "mass_concentration_of_hcc140a_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hcfc141b_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hcfc141b_in_air.json index 6888468cb..cafe6b16a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hcfc141b_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hcfc141b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hcfc141b_in_air", + "id": "mass_concentration_of_hcfc141b_in_air", "type": "standard_name", "name": "mass_concentration_of_hcfc141b_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hcfc142b_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hcfc142b_in_air.json index 9b676dfc5..d45db599f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hcfc142b_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hcfc142b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hcfc142b_in_air", + "id": "mass_concentration_of_hcfc142b_in_air", "type": "standard_name", "name": "mass_concentration_of_hcfc142b_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hcfc22_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hcfc22_in_air.json index 9d3677d65..1274250dc 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hcfc22_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hcfc22_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hcfc22_in_air", + "id": "mass_concentration_of_hcfc22_in_air", "type": "standard_name", "name": "mass_concentration_of_hcfc22_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hexachlorobiphenyl_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hexachlorobiphenyl_in_air.json index 169ae5378..0bb0bea08 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hexachlorobiphenyl_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hexachlorobiphenyl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hexachlorobiphenyl_in_air", + "id": "mass_concentration_of_hexachlorobiphenyl_in_air", "type": "standard_name", "name": "mass_concentration_of_hexachlorobiphenyl_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hexachlorobiphenyl is C12H4Cl6. This structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hox_expressed_as_hydrogen_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hox_expressed_as_hydrogen_in_air.json index 4089e81e7..7f5988997 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hox_expressed_as_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hox_expressed_as_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hox_expressed_as_hydrogen_in_air", + "id": "mass_concentration_of_hox_expressed_as_hydrogen_in_air", "type": "standard_name", "name": "mass_concentration_of_hox_expressed_as_hydrogen_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"HOx\" means a combination of two radical species containing hydrogen and oxygen: OH and HO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hydrogen_bromide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hydrogen_bromide_in_air.json index 86a8b7fdf..716befd17 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hydrogen_bromide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hydrogen_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hydrogen_bromide_in_air", + "id": "mass_concentration_of_hydrogen_bromide_in_air", "type": "standard_name", "name": "mass_concentration_of_hydrogen_bromide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hydrogen_chloride_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hydrogen_chloride_in_air.json index c66ba94ca..50af1215b 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hydrogen_chloride_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hydrogen_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hydrogen_chloride_in_air", + "id": "mass_concentration_of_hydrogen_chloride_in_air", "type": "standard_name", "name": "mass_concentration_of_hydrogen_chloride_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hydrogen_cyanide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hydrogen_cyanide_in_air.json index 486655283..7a84b1777 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hydrogen_cyanide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hydrogen_cyanide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hydrogen_cyanide_in_air", + "id": "mass_concentration_of_hydrogen_cyanide_in_air", "type": "standard_name", "name": "mass_concentration_of_hydrogen_cyanide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hydrogen_peroxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hydrogen_peroxide_in_air.json index 7d7c96846..b86f72473 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hydrogen_peroxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hydrogen_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hydrogen_peroxide_in_air", + "id": "mass_concentration_of_hydrogen_peroxide_in_air", "type": "standard_name", "name": "mass_concentration_of_hydrogen_peroxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hydroperoxyl_radical_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hydroperoxyl_radical_in_air.json index 863f1542c..a02bd44eb 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hydroperoxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hydroperoxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hydroperoxyl_radical_in_air", + "id": "mass_concentration_of_hydroperoxyl_radical_in_air", "type": "standard_name", "name": "mass_concentration_of_hydroperoxyl_radical_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for the hydroperoxyl radical is HO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hydroxyl_radical_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hydroxyl_radical_in_air.json index 2570e82a9..187d0d263 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hydroxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hydroxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hydroxyl_radical_in_air", + "id": "mass_concentration_of_hydroxyl_radical_in_air", "type": "standard_name", "name": "mass_concentration_of_hydroxyl_radical_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hypobromous_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hypobromous_acid_in_air.json index 42323ecd8..237d355c4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hypobromous_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hypobromous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hypobromous_acid_in_air", + "id": "mass_concentration_of_hypobromous_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_hypobromous_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/mass_concentration_of_hypochlorous_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_hypochlorous_acid_in_air.json index dfc8a6c92..8ac8d3a45 100644 --- a/data_descriptors/standard_name/mass_concentration_of_hypochlorous_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_hypochlorous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_hypochlorous_acid_in_air", + "id": "mass_concentration_of_hypochlorous_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_hypochlorous_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/mass_concentration_of_inorganic_bromine_in_air.json b/data_descriptors/standard_name/mass_concentration_of_inorganic_bromine_in_air.json index 88000da59..84129e9dd 100644 --- a/data_descriptors/standard_name/mass_concentration_of_inorganic_bromine_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_inorganic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_inorganic_bromine_in_air", + "id": "mass_concentration_of_inorganic_bromine_in_air", "type": "standard_name", "name": "mass_concentration_of_inorganic_bromine_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_inorganic_chlorine_in_air.json b/data_descriptors/standard_name/mass_concentration_of_inorganic_chlorine_in_air.json index 8a436306f..40cc8e7c3 100644 --- a/data_descriptors/standard_name/mass_concentration_of_inorganic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_inorganic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_inorganic_chlorine_in_air", + "id": "mass_concentration_of_inorganic_chlorine_in_air", "type": "standard_name", "name": "mass_concentration_of_inorganic_chlorine_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. \"Inorganic chlorine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"clox\" are used for quantities that contain all inorganic chlorine species except HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_inorganic_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_inorganic_nitrogen_in_sea_water.json index 8bea2aecc..ef75d5fd0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_inorganic_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_inorganic_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_inorganic_nitrogen_in_sea_water", + "id": "mass_concentration_of_inorganic_nitrogen_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_inorganic_nitrogen_in_sea_water", "description": "'Mass concentration' means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Inorganic nitrogen' describes a family of chemical species which, in an ocean model, usually includes nitrite, nitrate and ammonium which act as nitrogen nutrients. 'Inorganic nitrogen' is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_concentration_of_iron_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_iron_in_sea_floor_sediment.json index 86cee5106..cd25144b1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_iron_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_iron_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_iron_in_sea_floor_sediment", + "id": "mass_concentration_of_iron_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_iron_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Iron means iron in all chemical forms, commonly referred to as \"total iron\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_isoprene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_isoprene_in_air.json index 12ed801b3..00763fac0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_isoprene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_isoprene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_isoprene_in_air", + "id": "mass_concentration_of_isoprene_in_air", "type": "standard_name", "name": "mass_concentration_of_isoprene_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_lead_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_lead_in_sea_floor_sediment.json index 3e81d73d2..c8963b6fb 100644 --- a/data_descriptors/standard_name/mass_concentration_of_lead_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_lead_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_lead_in_sea_floor_sediment", + "id": "mass_concentration_of_lead_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_lead_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Lead means lead in all chemical forms, commonly referred to as \"total lead\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_limonene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_limonene_in_air.json index 4b26da84a..f0515c2c5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_limonene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_limonene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_limonene_in_air", + "id": "mass_concentration_of_limonene_in_air", "type": "standard_name", "name": "mass_concentration_of_limonene_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_liquid_water_in_air.json b/data_descriptors/standard_name/mass_concentration_of_liquid_water_in_air.json index 6ed65e164..94bdfb5e8 100644 --- a/data_descriptors/standard_name/mass_concentration_of_liquid_water_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_liquid_water_in_air", + "id": "mass_concentration_of_liquid_water_in_air", "type": "standard_name", "name": "mass_concentration_of_liquid_water_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The mass concentration of liquid water takes into account all cloud droplets and liquid precipitation regardless of drop size or fall speed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_lithium_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_lithium_in_sea_floor_sediment.json index ea3d6f85b..e83afdf46 100644 --- a/data_descriptors/standard_name/mass_concentration_of_lithium_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_lithium_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_lithium_in_sea_floor_sediment", + "id": "mass_concentration_of_lithium_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_lithium_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Lithium means lithium in all chemical forms, commonly referred to as \"total lithium\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_lutein_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_lutein_in_sea_water.json index dd8c48766..7417a5720 100644 --- a/data_descriptors/standard_name/mass_concentration_of_lutein_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_lutein_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_lutein_in_sea_water", + "id": "mass_concentration_of_lutein_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_lutein_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of lutein is C40H56O2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_manganese_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_manganese_in_sea_floor_sediment.json index 59e62e88c..2a373152a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_manganese_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_manganese_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_manganese_in_sea_floor_sediment", + "id": "mass_concentration_of_manganese_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_manganese_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Manganese means manganese in all chemical forms, commonly referred to as \"total manganese\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_mercury_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_mercury_dry_aerosol_particles_in_air.json index d29dde010..0655d309d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_mercury_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_mercury_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_mercury_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_mercury_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_mercury_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_concentration_of_mercury_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_mercury_in_sea_floor_sediment.json index 8979a273d..e24049bdb 100644 --- a/data_descriptors/standard_name/mass_concentration_of_mercury_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_mercury_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_mercury_in_sea_floor_sediment", + "id": "mass_concentration_of_mercury_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_mercury_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Mercury means mercury in all chemical forms, commonly referred to as \"total mercury\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_methane_in_air.json b/data_descriptors/standard_name/mass_concentration_of_methane_in_air.json index 43c9076fa..f32646fed 100644 --- a/data_descriptors/standard_name/mass_concentration_of_methane_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_methane_in_air", + "id": "mass_concentration_of_methane_in_air", "type": "standard_name", "name": "mass_concentration_of_methane_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_methanol_in_air.json b/data_descriptors/standard_name/mass_concentration_of_methanol_in_air.json index 4951d2e01..7adad4dd2 100644 --- a/data_descriptors/standard_name/mass_concentration_of_methanol_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_methanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_methanol_in_air", + "id": "mass_concentration_of_methanol_in_air", "type": "standard_name", "name": "mass_concentration_of_methanol_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/mass_concentration_of_methyl_bromide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_methyl_bromide_in_air.json index 79def0d13..9969cb787 100644 --- a/data_descriptors/standard_name/mass_concentration_of_methyl_bromide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_methyl_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_methyl_bromide_in_air", + "id": "mass_concentration_of_methyl_bromide_in_air", "type": "standard_name", "name": "mass_concentration_of_methyl_bromide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_methyl_chloride_in_air.json b/data_descriptors/standard_name/mass_concentration_of_methyl_chloride_in_air.json index e29bb9b99..ecfea26f3 100644 --- a/data_descriptors/standard_name/mass_concentration_of_methyl_chloride_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_methyl_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_methyl_chloride_in_air", + "id": "mass_concentration_of_methyl_chloride_in_air", "type": "standard_name", "name": "mass_concentration_of_methyl_chloride_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/mass_concentration_of_methyl_hydroperoxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_methyl_hydroperoxide_in_air.json index 6207364a1..d5a6632d2 100644 --- a/data_descriptors/standard_name/mass_concentration_of_methyl_hydroperoxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_methyl_hydroperoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_methyl_hydroperoxide_in_air", + "id": "mass_concentration_of_methyl_hydroperoxide_in_air", "type": "standard_name", "name": "mass_concentration_of_methyl_hydroperoxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/mass_concentration_of_methyl_peroxy_radical_in_air.json b/data_descriptors/standard_name/mass_concentration_of_methyl_peroxy_radical_in_air.json index 59ca29f2e..3b1913eae 100644 --- a/data_descriptors/standard_name/mass_concentration_of_methyl_peroxy_radical_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_methyl_peroxy_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_methyl_peroxy_radical_in_air", + "id": "mass_concentration_of_methyl_peroxy_radical_in_air", "type": "standard_name", "name": "mass_concentration_of_methyl_peroxy_radical_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl_peroxy_radical is CH3O2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water.json index 77b567d1c..c08ca5746 100644 --- a/data_descriptors/standard_name/mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_microphytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Microphytoplankton are phytoplankton between 20 and 200 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json index 2b3d0f79f..f37b80e4d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_molecular_hydrogen_in_air.json b/data_descriptors/standard_name/mass_concentration_of_molecular_hydrogen_in_air.json index 1474ffa2e..952ff40fe 100644 --- a/data_descriptors/standard_name/mass_concentration_of_molecular_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_molecular_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_molecular_hydrogen_in_air", + "id": "mass_concentration_of_molecular_hydrogen_in_air", "type": "standard_name", "name": "mass_concentration_of_molecular_hydrogen_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water.json index 655b3bc84..0d0dbe76d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water", + "id": "mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_monovinyl_chlorophyll_a_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water.json index b725d3421..c2b6c963a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_nanophytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Nanophytoplankton are phytoplankton between 2 and 20 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nickel_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_nickel_in_sea_floor_sediment.json index 7ee96f08e..7709e32be 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nickel_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_nickel_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nickel_in_sea_floor_sediment", + "id": "mass_concentration_of_nickel_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_nickel_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Nickel means nickel in all chemical forms, commonly referred to as \"total nickel\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitrate_dry_aerosol_particles_in_air.json index c1b9cb770..8a7c5e1b0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrate_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_nitrate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_nitrate_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrate_radical_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitrate_radical_in_air.json index b1eeef96f..19275bd7c 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrate_radical_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrate_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrate_radical_in_air", + "id": "mass_concentration_of_nitrate_radical_in_air", "type": "standard_name", "name": "mass_concentration_of_nitrate_radical_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitric_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitric_acid_in_air.json index 2b127e038..19a0ac951 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitric_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitric_acid_in_air", + "id": "mass_concentration_of_nitric_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_nitric_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json index f04dec51e..21ff74b2d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The chemical formula for nitric acid is HNO3. Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrogen_dioxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitrogen_dioxide_in_air.json index a25579beb..8f8162c54 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrogen_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrogen_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrogen_dioxide_in_air", + "id": "mass_concentration_of_nitrogen_dioxide_in_air", "type": "standard_name", "name": "mass_concentration_of_nitrogen_dioxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrogen_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_nitrogen_in_sea_floor_sediment.json index 11f9d321c..d4b389ff7 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrogen_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrogen_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrogen_in_sea_floor_sediment", + "id": "mass_concentration_of_nitrogen_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_nitrogen_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Total nitrogen means nitrogen in all chemical forms. \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrogen_monoxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitrogen_monoxide_in_air.json index be9fa0752..e79286479 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrogen_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrogen_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrogen_monoxide_in_air", + "id": "mass_concentration_of_nitrogen_monoxide_in_air", "type": "standard_name", "name": "mass_concentration_of_nitrogen_monoxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrous_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitrous_acid_in_air.json index fb5c56144..b5d859e1a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrous_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrous_acid_in_air", + "id": "mass_concentration_of_nitrous_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_nitrous_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nitrous_oxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nitrous_oxide_in_air.json index d047af0ea..966205f8f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nitrous_oxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nitrous_oxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nitrous_oxide_in_air", + "id": "mass_concentration_of_nitrous_oxide_in_air", "type": "standard_name", "name": "mass_concentration_of_nitrous_oxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nmvoc_expressed_as_carbon_in_air.json index e476ced22..1de4ee1d6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nmvoc_expressed_as_carbon_in_air", + "id": "mass_concentration_of_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_concentration_of_nmvoc_expressed_as_carbon_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_concentration_of_nox_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mass_concentration_of_nox_expressed_as_nitrogen_in_air.json index f02a84ce7..4355a2639 100644 --- a/data_descriptors/standard_name/mass_concentration_of_nox_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_nox_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_nox_expressed_as_nitrogen_in_air", + "id": "mass_concentration_of_nox_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mass_concentration_of_nox_expressed_as_nitrogen_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mass_concentration_of_noy_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mass_concentration_of_noy_expressed_as_nitrogen_in_air.json index 733bc320b..84222e0bb 100644 --- a/data_descriptors/standard_name/mass_concentration_of_noy_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_noy_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_noy_expressed_as_nitrogen_in_air", + "id": "mass_concentration_of_noy_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mass_concentration_of_noy_expressed_as_nitrogen_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air.json index b3aa98832..fc1df11b6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_organic_carbon_in_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"organic carbon aerosol\" refers to the carbonaceous fraction of particulate matter contained in any of the vast number of compounds where carbon is chemically combined with hydrogen and other elements like O, S, N, P, Cl, etc. In measurements of carbonaceous aerosols, organic carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air.json index 00fe13d53..7c72dbc58 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_organic_carbon_in_pm10_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. Chemically, \"organic carbon aerosol\" refers to the carbonaceous fraction of particulate matter contained in any of the vast number of compounds where carbon is chemically combined with hydrogen and other elements like O, S, N, P, Cl, etc. In measurements of carbonaceous aerosols, organic carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air.json index 273f7b979..b11ab75e1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_organic_carbon_in_pm1_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. Chemically, \"organic carbon aerosol\" refers to the carbonaceous fraction of particulate matter contained in any of the vast number of compounds where carbon is chemically combined with hydrogen and other elements like O, S, N, P, Cl, etc. In measurements of carbonaceous aerosols, organic carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air.json index 8dac342c0..d8e7a3a32 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_organic_carbon_in_pm2p5_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. Chemically, \"organic carbon aerosol\" refers to the carbonaceous fraction of particulate matter contained in any of the vast number of compounds where carbon is chemically combined with hydrogen and other elements like O, S, N, P, Cl, etc. In measurements of carbonaceous aerosols, organic carbon samples may also include some inorganic carbon compounds, whose mass is neglected and assumed to be distributed between the elemental and organic carbon components of the aerosol particles. Reference: Petzold, A., Ogren, J. A., Fiebig, M., Laj, P., Li, S.-M., Baltensperger, U., Holzer-Popp, T., Kinne, S., Pappalardo, G., Sugimoto, N., Wehrli, C., Wiedensohler, A., and Zhang, X.-Y.: Recommendations for reporting \"black carbon\" measurements, Atmos. Chem. Phys., 13, 8365\u20138379, https://doi.org/10.5194/acp-13-8365-2013, 2013.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_sea_floor_sediment.json index 7f2fd42c9..6d13bd03a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_carbon_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_carbon_in_sea_floor_sediment", + "id": "mass_concentration_of_organic_carbon_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_organic_carbon_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Organic carbon describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json index 1b1c2efd9..d7b3a8c74 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Organic detritus are particles of debris from decaying plants and animals.", diff --git a/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json index cb55741c7..1d0f4f6f6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water", + "id": "mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Organic detritus are particles of debris from decaying plants and animals.", diff --git a/data_descriptors/standard_name/mass_concentration_of_oxygen_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_oxygen_in_sea_water.json index 48efa3db2..b5760a48d 100644 --- a/data_descriptors/standard_name/mass_concentration_of_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_oxygen_in_sea_water", + "id": "mass_concentration_of_oxygen_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_oxygen_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mass_concentration_of_oxygenated_hydrocarbons_in_air.json b/data_descriptors/standard_name/mass_concentration_of_oxygenated_hydrocarbons_in_air.json index 685add61a..c2a001502 100644 --- a/data_descriptors/standard_name/mass_concentration_of_oxygenated_hydrocarbons_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_oxygenated_hydrocarbons_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_oxygenated_hydrocarbons_in_air", + "id": "mass_concentration_of_oxygenated_hydrocarbons_in_air", "type": "standard_name", "name": "mass_concentration_of_oxygenated_hydrocarbons_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"Oxygenated\" means containing oxygen. \"Hydrocarbon\" means a compound containing hydrogen and carbon.", diff --git a/data_descriptors/standard_name/mass_concentration_of_ozone_in_air.json b/data_descriptors/standard_name/mass_concentration_of_ozone_in_air.json index 587aea227..6a65c56f6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_ozone_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_ozone_in_air", + "id": "mass_concentration_of_ozone_in_air", "type": "standard_name", "name": "mass_concentration_of_ozone_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ozone is O3.", diff --git a/data_descriptors/standard_name/mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air.json index 3bf6bced4..d31930f23 100644 --- a/data_descriptors/standard_name/mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_concentration_of_peridinin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_peridinin_in_sea_water.json index d00945f9a..bc078bd16 100644 --- a/data_descriptors/standard_name/mass_concentration_of_peridinin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_peridinin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_peridinin_in_sea_water", + "id": "mass_concentration_of_peridinin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_peridinin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/PERDXXXX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_peroxy_radicals_in_air.json b/data_descriptors/standard_name/mass_concentration_of_peroxy_radicals_in_air.json index 06dbf49e0..6d0d18b88 100644 --- a/data_descriptors/standard_name/mass_concentration_of_peroxy_radicals_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_peroxy_radicals_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_peroxy_radicals_in_air", + "id": "mass_concentration_of_peroxy_radicals_in_air", "type": "standard_name", "name": "mass_concentration_of_peroxy_radicals_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The term \"peroxy_radicals\" means all organic and inorganic peroxy radicals. This includes HO2 and all organic peroxy radicals, sometimes referred to as RO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_peroxyacetyl_nitrate_in_air.json b/data_descriptors/standard_name/mass_concentration_of_peroxyacetyl_nitrate_in_air.json index 674a0a35c..c566596a9 100644 --- a/data_descriptors/standard_name/mass_concentration_of_peroxyacetyl_nitrate_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_peroxyacetyl_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_peroxyacetyl_nitrate_in_air", + "id": "mass_concentration_of_peroxyacetyl_nitrate_in_air", "type": "standard_name", "name": "mass_concentration_of_peroxyacetyl_nitrate_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl_nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/mass_concentration_of_peroxynitric_acid_in_air.json b/data_descriptors/standard_name/mass_concentration_of_peroxynitric_acid_in_air.json index ccaa2b53b..6a23f8d11 100644 --- a/data_descriptors/standard_name/mass_concentration_of_peroxynitric_acid_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_peroxynitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_peroxynitric_acid_in_air", + "id": "mass_concentration_of_peroxynitric_acid_in_air", "type": "standard_name", "name": "mass_concentration_of_peroxynitric_acid_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_petroleum_hydrocarbons_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_petroleum_hydrocarbons_in_sea_water.json index f3a7c87e4..eea492115 100644 --- a/data_descriptors/standard_name/mass_concentration_of_petroleum_hydrocarbons_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_petroleum_hydrocarbons_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_petroleum_hydrocarbons_in_sea_water", + "id": "mass_concentration_of_petroleum_hydrocarbons_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_petroleum_hydrocarbons_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Petroleum hydrocarbons are compounds containing just carbon and hydrogen originating from the fossil fuel crude oil.", diff --git a/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_floor_sediment.json index 292d89e18..e5b542cb3 100644 --- a/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_phaeopigments_in_sea_floor_sediment", + "id": "mass_concentration_of_phaeopigments_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_phaeopigments_in_sea_floor_sediment", "description": "Concentration of phaeopigment per unit volume of the water body, where the filtration size or collection method is unspecified (equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/. \"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Phaeopigments are a group of non-photosynthetic pigments that are the degradation product of algal chlorophyll pigments. Phaeopigments contain phaeophytin, which fluoresces in response to excitation light, and phaeophorbide, which is colorless and does not fluoresce (source: https://academic.oup.com/plankt/article/24/11/1221/1505482). Phaeopigment concentration commonly increases during the development phase of marine phytoplankton blooms, and declines in the post bloom stage (source: https://www.sciencedirect.com/science/article/pii/0967063793901018). \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_ice.json b/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_ice.json index 83fd2288e..d51764daf 100644 --- a/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_ice.json +++ b/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_phaeopigments_in_sea_ice", + "id": "mass_concentration_of_phaeopigments_in_sea_ice", "type": "standard_name", "name": "mass_concentration_of_phaeopigments_in_sea_ice", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Phaeopigments are non-photosynthetic pigments that are the degradation product of algal chlorophyll pigments. It is commonly formed during and after marine phytoplankton blooms. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_water.json index 6753d43c0..5283bbe90 100644 --- a/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_phaeopigments_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_phaeopigments_in_sea_water", + "id": "mass_concentration_of_phaeopigments_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_phaeopigments_in_sea_water", "description": "Concentration of phaeopigment per unit volume of the water body, where the filtration size or collection method is unspecified (equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/. \"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Phaeopigments are a group of non-photosynthetic pigments that are the degradation product of algal chlorophyll pigments. Phaeopigments contain phaeophytin, which fluoresces in response to excitation light, and phaeophorbide, which is colorless and does not fluoresce (source: https://academic.oup.com/plankt/article/24/11/1221/1505482). Phaeopigment concentration commonly increases during the development phase of marine phytoplankton blooms, and declines in the post bloom stage (source: https://www.sciencedirect.com/science/article/pii/0967063793901018).", diff --git a/data_descriptors/standard_name/mass_concentration_of_phosphate_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_phosphate_in_sea_water.json index db7a344bd..945abad65 100644 --- a/data_descriptors/standard_name/mass_concentration_of_phosphate_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_phosphate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_phosphate_in_sea_water", + "id": "mass_concentration_of_phosphate_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_phosphate_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", diff --git a/data_descriptors/standard_name/mass_concentration_of_phosphorus_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_phosphorus_in_sea_floor_sediment.json index b98157c2c..19ef9dc96 100644 --- a/data_descriptors/standard_name/mass_concentration_of_phosphorus_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_phosphorus_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_phosphorus_in_sea_floor_sediment", + "id": "mass_concentration_of_phosphorus_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_phosphorus_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Phosphorus means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water.json index f28b2824f..2631b7ec5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Standard names also exist for the mass concentration of a number of components that make up the total phytoplankton population, such as diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton and miscellaneous phytoplankton. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms.", diff --git a/data_descriptors/standard_name/mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water.json index 6ff5d23d8..f9a0aaf04 100644 --- a/data_descriptors/standard_name/mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water", + "id": "mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms. Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_ambient_aerosol_particles_in_air.json index adb4e8928..208f64313 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of, respectively, \"relative_humidity\" and \"air_temperature.\"", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air.json index 83e268881..5ddb7836a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_ammonium_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for ammonium is NH4+.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air.json index ecf2ada1a..13a5de667 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_bromide_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the bromide anion is Br-.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air.json index f614641cb..b12a5be3f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_calcium_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the calcium dication is Ca(2+).", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air.json index c91ad0a37..f1bf26c11 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_chloride_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for chloride is Cl-.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air.json index 3dcb26e19..bcd2630ea 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_magnesium_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the magnesium dication is Mg(2+).", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air.json index 84fb4db25..275320e13 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_methanesulfonic_acid_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for methanesulfonic acid is CH3SO3H.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air.json index 8414f4132..1fee50b50 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_nitrate_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air.json index adac45b63..70b89e018 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_oxalate_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the oxalate dianion is C2O4(2-).", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air.json index 8a9f0f4a7..046743141 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_potassium_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the potassium cation is K+.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json index d73390ba5..ee42a7ae9 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", + "id": "mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air.json index 8a49c68bf..d7063e0e0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_sea_salt_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air.json index 9c7ff3052..4c2e0abd4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_sodium_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the sodium cation is Na+.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air.json index c773a50c7..8f88cf526 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm10_sulfate_dry_aerosol_particles_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm1_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm1_ambient_aerosol_particles_in_air.json index 9374d5540..3c9bd55e5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm1_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm1_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm1_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_pm1_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm1_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air.json index 10cad0514..06d06b104 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm2p5_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of \"relative_humidity\" and \"air_temperature.\"", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json index 24645eba7..5d70e459a 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", + "id": "mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "type": "standard_name", "name": "mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json index c3a7b94d5..0646c0a24 100644 --- a/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_pm2p5_sea_salt_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/mass_concentration_of_prasinoxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_prasinoxanthin_in_sea_water.json index 50ffbc749..3adf80396 100644 --- a/data_descriptors/standard_name/mass_concentration_of_prasinoxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_prasinoxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_prasinoxanthin_in_sea_water", + "id": "mass_concentration_of_prasinoxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_prasinoxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of prasinoxanthin is C40H56O4. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/PXAPXXXX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json index 810dad2fc..b7e3e06f1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Primary particulate organic matter \" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json index 5330a5b73..1aae5f4c1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Prokaryotes\" means all Bacteria and Archaea excluding photosynthetic cyanobacteria such as Synechococcus and Prochlorococcus or other separately named components of the prokaryotic population.", diff --git a/data_descriptors/standard_name/mass_concentration_of_propane_in_air.json b/data_descriptors/standard_name/mass_concentration_of_propane_in_air.json index cf07acc2e..88acf35e1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_propane_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_propane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_propane_in_air", + "id": "mass_concentration_of_propane_in_air", "type": "standard_name", "name": "mass_concentration_of_propane_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_propene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_propene_in_air.json index 5637cad03..ac9ec5b30 100644 --- a/data_descriptors/standard_name/mass_concentration_of_propene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_propene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_propene_in_air", + "id": "mass_concentration_of_propene_in_air", "type": "standard_name", "name": "mass_concentration_of_propene_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_radon_in_air.json b/data_descriptors/standard_name/mass_concentration_of_radon_in_air.json index b679c6f52..0bdb518dd 100644 --- a/data_descriptors/standard_name/mass_concentration_of_radon_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_radon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_radon_in_air", + "id": "mass_concentration_of_radon_in_air", "type": "standard_name", "name": "mass_concentration_of_radon_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/mass_concentration_of_rain_in_air.json b/data_descriptors/standard_name/mass_concentration_of_rain_in_air.json index 2d5794c82..940398001 100644 --- a/data_descriptors/standard_name/mass_concentration_of_rain_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_rain_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_rain_in_air", + "id": "mass_concentration_of_rain_in_air", "type": "standard_name", "name": "mass_concentration_of_rain_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Rain\" means drops of water falling through the atmosphere that have a diameter greater than 0.5 mm.", diff --git a/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json b/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json index aa3d96fa8..3804ed053 100644 --- a/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", + "id": "mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "type": "standard_name", "name": "mass_concentration_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_in_air.json index c32ba9d70..bba7f8e43 100644 --- a/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_sea_salt_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_sea_salt_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_sea_salt_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json index 5ae9aa065..b15d8e5e7 100644 --- a/data_descriptors/standard_name/mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Secondary particulate organic matter\" means particulate organic matter formed within the atmosphere from gaseous precursors. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_concentration_of_silicate_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_silicate_in_sea_water.json index 411ef3be2..f60ee780e 100644 --- a/data_descriptors/standard_name/mass_concentration_of_silicate_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_silicate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_silicate_in_sea_water", + "id": "mass_concentration_of_silicate_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_silicate_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", diff --git a/data_descriptors/standard_name/mass_concentration_of_silver_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_silver_in_sea_floor_sediment.json index 5701d05d8..9a8b4d983 100644 --- a/data_descriptors/standard_name/mass_concentration_of_silver_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_silver_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_silver_in_sea_floor_sediment", + "id": "mass_concentration_of_silver_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_silver_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Silver means silver in all chemical forms, commonly referred to as \"total silver\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_sulfate_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_sulfate_ambient_aerosol_particles_in_air.json index f07a060bc..a735991c6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_sulfate_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_sulfate_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_sulfate_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_sulfate_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_sulfate_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/mass_concentration_of_sulfate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_sulfate_dry_aerosol_particles_in_air.json index 13bcb90e6..3e2f859e0 100644 --- a/data_descriptors/standard_name/mass_concentration_of_sulfate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_sulfate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_sulfate_dry_aerosol_particles_in_air", + "id": "mass_concentration_of_sulfate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_sulfate_dry_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/mass_concentration_of_sulfur_dioxide_in_air.json b/data_descriptors/standard_name/mass_concentration_of_sulfur_dioxide_in_air.json index 3affd2d69..0c9d37f96 100644 --- a/data_descriptors/standard_name/mass_concentration_of_sulfur_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_sulfur_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_sulfur_dioxide_in_air", + "id": "mass_concentration_of_sulfur_dioxide_in_air", "type": "standard_name", "name": "mass_concentration_of_sulfur_dioxide_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/mass_concentration_of_suspended_matter_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_suspended_matter_in_sea_water.json index 4899ac6e9..083a2e82f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_suspended_matter_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_suspended_matter_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_suspended_matter_in_sea_water", + "id": "mass_concentration_of_suspended_matter_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_suspended_matter_in_sea_water", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", diff --git a/data_descriptors/standard_name/mass_concentration_of_terpenes_in_air.json b/data_descriptors/standard_name/mass_concentration_of_terpenes_in_air.json index 788060d48..a921d570f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_terpenes_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_terpenes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_terpenes_in_air", + "id": "mass_concentration_of_terpenes_in_air", "type": "standard_name", "name": "mass_concentration_of_terpenes_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Terpenes are hydrocarbons, that is, they contain only hydrogen and carbon combined in the general proportions (C5H8)n where n is an integer greater than on equal to one. The term \"terpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual terpene species, e.g., isoprene and limonene.", diff --git a/data_descriptors/standard_name/mass_concentration_of_toluene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_toluene_in_air.json index c39be3408..0a36382e6 100644 --- a/data_descriptors/standard_name/mass_concentration_of_toluene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_toluene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_toluene_in_air", + "id": "mass_concentration_of_toluene_in_air", "type": "standard_name", "name": "mass_concentration_of_toluene_in_air", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/mass_concentration_of_vanadium_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_vanadium_in_sea_floor_sediment.json index 555c5cdc9..3bff587d1 100644 --- a/data_descriptors/standard_name/mass_concentration_of_vanadium_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_vanadium_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_vanadium_in_sea_floor_sediment", + "id": "mass_concentration_of_vanadium_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_vanadium_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Vanadium means vanadium in all chemical forms, commonly referred to as \"total vanadium\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_violaxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_violaxanthin_in_sea_water.json index 6e3ffab99..bd89233e7 100644 --- a/data_descriptors/standard_name/mass_concentration_of_violaxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_violaxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_violaxanthin_in_sea_water", + "id": "mass_concentration_of_violaxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_violaxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of violaxanthin is C40H56O4.", diff --git a/data_descriptors/standard_name/mass_concentration_of_volcanic_ash_in_air.json b/data_descriptors/standard_name/mass_concentration_of_volcanic_ash_in_air.json index 8df5ab83c..7f5b5bd8f 100644 --- a/data_descriptors/standard_name/mass_concentration_of_volcanic_ash_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_volcanic_ash_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_volcanic_ash_in_air", + "id": "mass_concentration_of_volcanic_ash_in_air", "type": "standard_name", "name": "mass_concentration_of_volcanic_ash_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. \"Volcanic ash\" means the fine-grained products of explosive volcanic eruptions, such as minerals or crystals, older fragmented rock (e.g. andesite) and glass. Particles within a volcanic ash cloud have diameters less than 2 mm. \"Volcanic ash\" does not include non-volcanic dust.", diff --git a/data_descriptors/standard_name/mass_concentration_of_water_in_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_concentration_of_water_in_ambient_aerosol_particles_in_air.json index 2704e10fc..90a5e6ca5 100644 --- a/data_descriptors/standard_name/mass_concentration_of_water_in_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_water_in_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_water_in_ambient_aerosol_particles_in_air", + "id": "mass_concentration_of_water_in_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_concentration_of_water_in_ambient_aerosol_particles_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles.", diff --git a/data_descriptors/standard_name/mass_concentration_of_water_vapor_in_air.json b/data_descriptors/standard_name/mass_concentration_of_water_vapor_in_air.json index 05bbf36fb..1cbe02ef4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_water_vapor_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_water_vapor_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_water_vapor_in_air", + "id": "mass_concentration_of_water_vapor_in_air", "type": "standard_name", "name": "mass_concentration_of_water_vapor_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", diff --git a/data_descriptors/standard_name/mass_concentration_of_xylene_in_air.json b/data_descriptors/standard_name/mass_concentration_of_xylene_in_air.json index 64389b004..7db233b16 100644 --- a/data_descriptors/standard_name/mass_concentration_of_xylene_in_air.json +++ b/data_descriptors/standard_name/mass_concentration_of_xylene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_xylene_in_air", + "id": "mass_concentration_of_xylene_in_air", "type": "standard_name", "name": "mass_concentration_of_xylene_in_air", "description": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/mass_concentration_of_zeaxanthin_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_zeaxanthin_in_sea_water.json index 154d47b4b..6b1f0f2d4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_zeaxanthin_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_zeaxanthin_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_zeaxanthin_in_sea_water", + "id": "mass_concentration_of_zeaxanthin_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_zeaxanthin_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of zeaxanthin is C40H56O2. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/ZEAXXXXX/2/.", diff --git a/data_descriptors/standard_name/mass_concentration_of_zinc_in_sea_floor_sediment.json b/data_descriptors/standard_name/mass_concentration_of_zinc_in_sea_floor_sediment.json index 52491334a..e3447c0ee 100644 --- a/data_descriptors/standard_name/mass_concentration_of_zinc_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/mass_concentration_of_zinc_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_zinc_in_sea_floor_sediment", + "id": "mass_concentration_of_zinc_in_sea_floor_sediment", "type": "standard_name", "name": "mass_concentration_of_zinc_in_sea_floor_sediment", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Zinc means zinc in all chemical forms, commonly referred to as \"total zinc\". \"Sea floor sediment\" is sediment deposited at the sea bed.", diff --git a/data_descriptors/standard_name/mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json index 58b518833..7be2398b4 100644 --- a/data_descriptors/standard_name/mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", + "id": "mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mass_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "description": "\"Mass concentration\" means mass per unit volume and is used in the construction \"mass_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Zooplankton\" means the total zooplankton population, with components such as mesozooplankton, microzooplankton and miscellaneous zooplankton.", diff --git a/data_descriptors/standard_name/mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json b/data_descriptors/standard_name/mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json index 7a229f7eb..7de21b907 100644 --- a/data_descriptors/standard_name/mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", + "id": "mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "type": "standard_name", "name": "mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json b/data_descriptors/standard_name/mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json index e0b2a3bea..07db3a7b1 100644 --- a/data_descriptors/standard_name/mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", + "id": "mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "type": "standard_name", "name": "mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json b/data_descriptors/standard_name/mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json index 7d7b85353..ce4697b8b 100644 --- a/data_descriptors/standard_name/mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", + "id": "mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "type": "standard_name", "name": "mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites.", diff --git a/data_descriptors/standard_name/mass_content_of_cloud_condensed_water_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_cloud_condensed_water_in_atmosphere_layer.json index ecd02fe8f..98f69c18a 100644 --- a/data_descriptors/standard_name/mass_content_of_cloud_condensed_water_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_cloud_condensed_water_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_cloud_condensed_water_in_atmosphere_layer", + "id": "mass_content_of_cloud_condensed_water_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_cloud_condensed_water_in_atmosphere_layer", "description": "\"condensed_water\" means liquid and ice. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/mass_content_of_cloud_ice_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_cloud_ice_in_atmosphere_layer.json index ae72aed4e..5fbdc8412 100644 --- a/data_descriptors/standard_name/mass_content_of_cloud_ice_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_cloud_ice_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_cloud_ice_in_atmosphere_layer", + "id": "mass_content_of_cloud_ice_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_cloud_ice_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/mass_content_of_cloud_liquid_water_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_cloud_liquid_water_in_atmosphere_layer.json index c433de0b9..004fa1db3 100644 --- a/data_descriptors/standard_name/mass_content_of_cloud_liquid_water_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_cloud_liquid_water_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_cloud_liquid_water_in_atmosphere_layer", + "id": "mass_content_of_cloud_liquid_water_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_cloud_liquid_water_in_atmosphere_layer", "description": "The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. \"Content\" indicates a quantity per unit area. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json b/data_descriptors/standard_name/mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json index b3e9f0d1f..be2b34975 100644 --- a/data_descriptors/standard_name/mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", + "id": "mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "type": "standard_name", "name": "mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites.", diff --git a/data_descriptors/standard_name/mass_content_of_water_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_water_in_atmosphere_layer.json index 63e85a136..47c6e3af8 100644 --- a/data_descriptors/standard_name/mass_content_of_water_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_water_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_in_atmosphere_layer", + "id": "mass_content_of_water_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_water_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/mass_content_of_water_in_soil.json b/data_descriptors/standard_name/mass_content_of_water_in_soil.json index 1208ef0e4..2272c5665 100644 --- a/data_descriptors/standard_name/mass_content_of_water_in_soil.json +++ b/data_descriptors/standard_name/mass_content_of_water_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_in_soil", + "id": "mass_content_of_water_in_soil", "type": "standard_name", "name": "mass_content_of_water_in_soil", "description": "\"Water\" means water in all phases. \"Content\" indicates a quantity per unit area. The mass content of water in soil refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used.", diff --git a/data_descriptors/standard_name/mass_content_of_water_in_soil_layer.json b/data_descriptors/standard_name/mass_content_of_water_in_soil_layer.json index 70d8807d2..0bdbf1e4c 100644 --- a/data_descriptors/standard_name/mass_content_of_water_in_soil_layer.json +++ b/data_descriptors/standard_name/mass_content_of_water_in_soil_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_in_soil_layer", + "id": "mass_content_of_water_in_soil_layer", "type": "standard_name", "name": "mass_content_of_water_in_soil_layer", "description": "\"Content\" indicates a quantity per unit area. \"Water\" means water in all phases. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).", diff --git a/data_descriptors/standard_name/mass_content_of_water_in_soil_layer_defined_by_root_depth.json b/data_descriptors/standard_name/mass_content_of_water_in_soil_layer_defined_by_root_depth.json index a274076a9..f2c031798 100644 --- a/data_descriptors/standard_name/mass_content_of_water_in_soil_layer_defined_by_root_depth.json +++ b/data_descriptors/standard_name/mass_content_of_water_in_soil_layer_defined_by_root_depth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_in_soil_layer_defined_by_root_depth", + "id": "mass_content_of_water_in_soil_layer_defined_by_root_depth", "type": "standard_name", "name": "mass_content_of_water_in_soil_layer_defined_by_root_depth", "description": "\"Content\" indicates a quantity per unit area. The content of a soil layer is the vertical integral of the specified quantity within the layer. The quantity with standard name mass_content_of_water_in_soil_layer_defined_by_root_depth is the vertical integral between the surface and the depth to which plant roots penetrate. A coordinate variable or scalar coordinate variable with standard name root_depth can be used to specify the extent of the layer. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/mass_content_of_water_vapor_containing_17O_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_water_vapor_containing_17O_in_atmosphere_layer.json index f94d8b3f5..d10da9b31 100644 --- a/data_descriptors/standard_name/mass_content_of_water_vapor_containing_17O_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_water_vapor_containing_17O_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_vapor_containing_17O_in_atmosphere_layer", + "id": "mass_content_of_water_vapor_containing_17O_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_water_vapor_containing_17O_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. The chemical formula for water is H2O. \"O\" means the element \"oxygen\" and \"17O\" is the stable isotope \"oxygen-17\".", diff --git a/data_descriptors/standard_name/mass_content_of_water_vapor_containing_18O_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_water_vapor_containing_18O_in_atmosphere_layer.json index 73869f3da..a7b304e11 100644 --- a/data_descriptors/standard_name/mass_content_of_water_vapor_containing_18O_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_water_vapor_containing_18O_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_vapor_containing_18O_in_atmosphere_layer", + "id": "mass_content_of_water_vapor_containing_18O_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_water_vapor_containing_18O_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. The chemical formula for water is H2O. \"O\" means the element \"oxygen\" and \"18O\" is the stable isotope \"oxygen-18\".", diff --git a/data_descriptors/standard_name/mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer.json index 638d0685a..19ca4dcbd 100644 --- a/data_descriptors/standard_name/mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer", + "id": "mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be \"model_level_number\", but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. The chemical formula for water is H2O. \"H\" means the element \"hydrogen\" and \"2H\" is the stable isotope \"hydrogen-2\", usually called \"deuterium\". The construction \"X_containing_single_Y\" means the standard name refers to only that part of X composed of molecules containing a single atom of isotope Y.", diff --git a/data_descriptors/standard_name/mass_content_of_water_vapor_in_atmosphere_layer.json b/data_descriptors/standard_name/mass_content_of_water_vapor_in_atmosphere_layer.json index 4dbac4f19..dda6640aa 100644 --- a/data_descriptors/standard_name/mass_content_of_water_vapor_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mass_content_of_water_vapor_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_content_of_water_vapor_in_atmosphere_layer", + "id": "mass_content_of_water_vapor_in_atmosphere_layer", "type": "standard_name", "name": "mass_content_of_water_vapor_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting.json index 8300a1725..312526b0f 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting", + "id": "mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting", "type": "standard_name", "name": "mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The definition of \"crop\" is model dependent, for example, some models may include fruit trees, trees grown for timber or other types of agricultural and forestry planting as crops. Crop harvesting means the human activity of collecting plant materials for the purpose of turning them into forestry or agricultural products.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation.json index 28529330a..adc134ea5 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_litter_from_vegetation", + "id": "mass_flux_of_carbon_into_litter_from_vegetation", "type": "standard_name", "name": "mass_flux_of_carbon_into_litter_from_vegetation", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The sum of the quantities with standard names mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality and mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence is mass_flux_of_carbon_into_litter_from_vegetation.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality.json index 9f025fa7d..cef76698c 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality", + "id": "mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality", "type": "standard_name", "name": "mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The term \"mortality\" means the loss of living biomass due to plant death. It refers to the death of the whole plant, not only the leaves.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence.json index b4d0429af..05b2dc92a 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence", + "id": "mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence", "type": "standard_name", "name": "mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The term \"senescence\" means loss of living biomass excluding plant death, e.g. leaf drop and other seasonal effects. The term refers to changes in the whole plant and is not confined only to leaf drop.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_sea_water_from_rivers.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_sea_water_from_rivers.json index 4fa3796ca..fb00911e0 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_sea_water_from_rivers.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_sea_water_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_sea_water_from_rivers", + "id": "mass_flux_of_carbon_into_sea_water_from_rivers", "type": "standard_name", "name": "mass_flux_of_carbon_into_sea_water_from_rivers", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality.json index 83106c2ed..c260cf42a 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality", + "id": "mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality", "type": "standard_name", "name": "mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The term \"mortality\" means the loss of living biomass due to plant death. It refers to the death of the whole plant, not only the leaves.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence.json b/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence.json index 4ef2c0a46..998b28f52 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence", + "id": "mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence", "type": "standard_name", "name": "mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The term \"senescence\" means loss of living biomass excluding plant death, e.g. leaf drop and other seasonal effects. The term refers to changes in the whole plant and is not confined only to leaf drop.", diff --git a/data_descriptors/standard_name/mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff.json b/data_descriptors/standard_name/mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff.json index f68340205..8baebde00 100644 --- a/data_descriptors/standard_name/mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff.json +++ b/data_descriptors/standard_name/mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff", + "id": "mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff", "type": "standard_name", "name": "mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Leaching\" means the loss of water soluble chemical species from soil. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers.json b/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers.json index 2d890304f..5728d8059 100644 --- a/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers.json +++ b/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers", + "id": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers", "type": "standard_name", "name": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization.json b/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization.json index 5f40bb4d8..492137494 100644 --- a/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization.json +++ b/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization", + "id": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization", "type": "standard_name", "name": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Remineralization is the degradation of organic matter into inorganic forms of carbon, nitrogen, phosphorus and other micronutrients, which consumes oxygen and releases energy. Immobilisation of nitrogen refers to retention of nitrogen by micro-organisms under certain conditions, making it unavailable for plants.", diff --git a/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff.json b/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff.json index 9618315cf..5337d4276 100644 --- a/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff.json +++ b/data_descriptors/standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff", + "id": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff", "type": "standard_name", "name": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil_due_to_leaching_and_runoff", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Leaching\" means the loss of water soluble chemical species from soil. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/mass_fraction_of_acetic_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_acetic_acid_in_air.json index 24a1c000b..ae863b71e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_acetic_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_acetic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_acetic_acid_in_air", + "id": "mass_fraction_of_acetic_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_acetic_acid_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/mass_fraction_of_aceto_nitrile_in_air.json b/data_descriptors/standard_name/mass_fraction_of_aceto_nitrile_in_air.json index 3b63200cf..9e74904da 100644 --- a/data_descriptors/standard_name/mass_fraction_of_aceto_nitrile_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_aceto_nitrile_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_aceto_nitrile_in_air", + "id": "mass_fraction_of_aceto_nitrile_in_air", "type": "standard_name", "name": "mass_fraction_of_aceto_nitrile_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/mass_fraction_of_alkanes_in_air.json b/data_descriptors/standard_name/mass_fraction_of_alkanes_in_air.json index 6ec920504..dd0dd85fa 100644 --- a/data_descriptors/standard_name/mass_fraction_of_alkanes_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_alkanes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_alkanes_in_air", + "id": "mass_fraction_of_alkanes_in_air", "type": "standard_name", "name": "mass_fraction_of_alkanes_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Alkanes are saturated hydrocarbons, i.e. they do not contain any chemical double bonds. Alkanes contain only hydrogen and carbon combined in the general proportions C(n)H(2n+2); \"alkanes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkane species, e.g., methane and ethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_alkenes_in_air.json b/data_descriptors/standard_name/mass_fraction_of_alkenes_in_air.json index a485ed635..140aa7324 100644 --- a/data_descriptors/standard_name/mass_fraction_of_alkenes_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_alkenes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_alkenes_in_air", + "id": "mass_fraction_of_alkenes_in_air", "type": "standard_name", "name": "mass_fraction_of_alkenes_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Alkenes are unsaturated hydrocarbons as they contain chemical double bonds between adjacent carbon atoms. Alkenes contain only hydrogen and carbon combined in the general proportions C(n)H(2n); \"alkenes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkene species, e.g., ethene and propene.", diff --git a/data_descriptors/standard_name/mass_fraction_of_alpha_hexachlorocyclohexane_in_air.json b/data_descriptors/standard_name/mass_fraction_of_alpha_hexachlorocyclohexane_in_air.json index 8ebef0463..713dd303a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_alpha_hexachlorocyclohexane_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_alpha_hexachlorocyclohexane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_alpha_hexachlorocyclohexane_in_air", + "id": "mass_fraction_of_alpha_hexachlorocyclohexane_in_air", "type": "standard_name", "name": "mass_fraction_of_alpha_hexachlorocyclohexane_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for alpha_hexachlorocyclohexane is C6H6Cl6.", diff --git a/data_descriptors/standard_name/mass_fraction_of_alpha_pinene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_alpha_pinene_in_air.json index 430048920..4138ec24a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_alpha_pinene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_alpha_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_alpha_pinene_in_air", + "id": "mass_fraction_of_alpha_pinene_in_air", "type": "standard_name", "name": "mass_fraction_of_alpha_pinene_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/mass_fraction_of_ammonia_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ammonia_in_air.json index 8ddb87336..4da1e826a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ammonia_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ammonia_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ammonia_in_air", + "id": "mass_fraction_of_ammonia_in_air", "type": "standard_name", "name": "mass_fraction_of_ammonia_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/mass_fraction_of_ammonium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ammonium_dry_aerosol_particles_in_air.json index 6948ddeb3..b78675b1e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ammonium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ammonium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ammonium_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_ammonium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_ammonium_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Mass_fraction_of_ammonium\" means that the mass is expressed as mass of NH4. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json index 74f90e92c..ddf6fbb5f 100644 --- a/data_descriptors/standard_name/mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/mass_fraction_of_aromatic_compounds_in_air.json b/data_descriptors/standard_name/mass_fraction_of_aromatic_compounds_in_air.json index 90599043a..869313cb7 100644 --- a/data_descriptors/standard_name/mass_fraction_of_aromatic_compounds_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_aromatic_compounds_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_aromatic_compounds_in_air", + "id": "mass_fraction_of_aromatic_compounds_in_air", "type": "standard_name", "name": "mass_fraction_of_aromatic_compounds_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Aromatic compounds in organic chemistry are compounds that contain at least one benzene ring of six carbon atoms joined by alternating single and double covalent bonds. The simplest aromatic compound is benzene itself. In standard names \"aromatic_compounds\" is the term used to describe the group of aromatic chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual aromatic species, e.g. benzene and xylene.", diff --git a/data_descriptors/standard_name/mass_fraction_of_atomic_bromine_in_air.json b/data_descriptors/standard_name/mass_fraction_of_atomic_bromine_in_air.json index 6dfb52505..d4b2e3265 100644 --- a/data_descriptors/standard_name/mass_fraction_of_atomic_bromine_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_atomic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_atomic_bromine_in_air", + "id": "mass_fraction_of_atomic_bromine_in_air", "type": "standard_name", "name": "mass_fraction_of_atomic_bromine_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic bromine is Br.", diff --git a/data_descriptors/standard_name/mass_fraction_of_atomic_chlorine_in_air.json b/data_descriptors/standard_name/mass_fraction_of_atomic_chlorine_in_air.json index d3580ab4d..6ac7f6142 100644 --- a/data_descriptors/standard_name/mass_fraction_of_atomic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_atomic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_atomic_chlorine_in_air", + "id": "mass_fraction_of_atomic_chlorine_in_air", "type": "standard_name", "name": "mass_fraction_of_atomic_chlorine_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/mass_fraction_of_atomic_nitrogen_in_air.json b/data_descriptors/standard_name/mass_fraction_of_atomic_nitrogen_in_air.json index ae27d19cc..18e66101d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_atomic_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_atomic_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_atomic_nitrogen_in_air", + "id": "mass_fraction_of_atomic_nitrogen_in_air", "type": "standard_name", "name": "mass_fraction_of_atomic_nitrogen_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/mass_fraction_of_benzene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_benzene_in_air.json index 7941101b2..d38c9e6dc 100644 --- a/data_descriptors/standard_name/mass_fraction_of_benzene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_benzene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_benzene_in_air", + "id": "mass_fraction_of_benzene_in_air", "type": "standard_name", "name": "mass_fraction_of_benzene_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_beta_pinene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_beta_pinene_in_air.json index 976cd0b27..88c7d59a8 100644 --- a/data_descriptors/standard_name/mass_fraction_of_beta_pinene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_beta_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_beta_pinene_in_air", + "id": "mass_fraction_of_beta_pinene_in_air", "type": "standard_name", "name": "mass_fraction_of_beta_pinene_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json index e13839f4e..a09ec7ea1 100644 --- a/data_descriptors/standard_name/mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes.", diff --git a/data_descriptors/standard_name/mass_fraction_of_bromine_chloride_in_air.json b/data_descriptors/standard_name/mass_fraction_of_bromine_chloride_in_air.json index f6f9ea799..981997ee1 100644 --- a/data_descriptors/standard_name/mass_fraction_of_bromine_chloride_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_bromine_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_bromine_chloride_in_air", + "id": "mass_fraction_of_bromine_chloride_in_air", "type": "standard_name", "name": "mass_fraction_of_bromine_chloride_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/mass_fraction_of_bromine_monoxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_bromine_monoxide_in_air.json index b69823d16..c58ac936d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_bromine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_bromine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_bromine_monoxide_in_air", + "id": "mass_fraction_of_bromine_monoxide_in_air", "type": "standard_name", "name": "mass_fraction_of_bromine_monoxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/mass_fraction_of_bromine_nitrate_in_air.json b/data_descriptors/standard_name/mass_fraction_of_bromine_nitrate_in_air.json index e9c8f29f7..a96149823 100644 --- a/data_descriptors/standard_name/mass_fraction_of_bromine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_bromine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_bromine_nitrate_in_air", + "id": "mass_fraction_of_bromine_nitrate_in_air", "type": "standard_name", "name": "mass_fraction_of_bromine_nitrate_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for bromine nitrate is BrONO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_brox_expressed_as_bromine_in_air.json b/data_descriptors/standard_name/mass_fraction_of_brox_expressed_as_bromine_in_air.json index 71a9db6ca..72b508e4d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_brox_expressed_as_bromine_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_brox_expressed_as_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_brox_expressed_as_bromine_in_air", + "id": "mass_fraction_of_brox_expressed_as_bromine_in_air", "type": "standard_name", "name": "mass_fraction_of_brox_expressed_as_bromine_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HBr and BrONO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_butane_in_air.json b/data_descriptors/standard_name/mass_fraction_of_butane_in_air.json index b548a2d5f..64910d3e9 100644 --- a/data_descriptors/standard_name/mass_fraction_of_butane_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_butane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_butane_in_air", + "id": "mass_fraction_of_butane_in_air", "type": "standard_name", "name": "mass_fraction_of_butane_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_in_air.json index 51b21ec10..14cc32ca6 100644 --- a/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_carbon_dioxide_in_air", + "id": "mass_fraction_of_carbon_dioxide_in_air", "type": "standard_name", "name": "mass_fraction_of_carbon_dioxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_tracer_in_air.json b/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_tracer_in_air.json index bf9103ce1..05fcdfa4b 100644 --- a/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_tracer_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_carbon_dioxide_tracer_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_carbon_dioxide_tracer_in_air", + "id": "mass_fraction_of_carbon_dioxide_tracer_in_air", "type": "standard_name", "name": "mass_fraction_of_carbon_dioxide_tracer_in_air", "description": "The chemical formula for carbon dioxide is CO2. Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". A \"tracer\" is a quantity advected by a model to facilitate analysis of flow patterns.", diff --git a/data_descriptors/standard_name/mass_fraction_of_carbon_monoxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_carbon_monoxide_in_air.json index 1fdeb44d1..11f7929d0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_carbon_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_carbon_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_carbon_monoxide_in_air", + "id": "mass_fraction_of_carbon_monoxide_in_air", "type": "standard_name", "name": "mass_fraction_of_carbon_monoxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/mass_fraction_of_carbon_tetrachloride_in_air.json b/data_descriptors/standard_name/mass_fraction_of_carbon_tetrachloride_in_air.json index feef5d643..1b4023cd8 100644 --- a/data_descriptors/standard_name/mass_fraction_of_carbon_tetrachloride_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_carbon_tetrachloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_carbon_tetrachloride_in_air", + "id": "mass_fraction_of_carbon_tetrachloride_in_air", "type": "standard_name", "name": "mass_fraction_of_carbon_tetrachloride_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cfc113_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cfc113_in_air.json index 0439a88cc..6ff5732ea 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cfc113_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cfc113_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cfc113_in_air", + "id": "mass_fraction_of_cfc113_in_air", "type": "standard_name", "name": "mass_fraction_of_cfc113_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cfc113a_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cfc113a_in_air.json index 41cff12b2..42cce74f4 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cfc113a_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cfc113a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cfc113a_in_air", + "id": "mass_fraction_of_cfc113a_in_air", "type": "standard_name", "name": "mass_fraction_of_cfc113a_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cfc114_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cfc114_in_air.json index efc341079..51218397e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cfc114_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cfc114_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cfc114_in_air", + "id": "mass_fraction_of_cfc114_in_air", "type": "standard_name", "name": "mass_fraction_of_cfc114_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cfc115_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cfc115_in_air.json index 31e8e5877..5407b1921 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cfc115_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cfc115_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cfc115_in_air", + "id": "mass_fraction_of_cfc115_in_air", "type": "standard_name", "name": "mass_fraction_of_cfc115_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cfc11_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cfc11_in_air.json index f6ee75f78..89f81b06a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cfc11_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cfc11_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cfc11_in_air", + "id": "mass_fraction_of_cfc11_in_air", "type": "standard_name", "name": "mass_fraction_of_cfc11_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cfc12_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cfc12_in_air.json index c1744029e..700c645fa 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cfc12_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cfc12_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cfc12_in_air", + "id": "mass_fraction_of_cfc12_in_air", "type": "standard_name", "name": "mass_fraction_of_cfc12_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_chlorine_dioxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_chlorine_dioxide_in_air.json index 49884ea47..4cc3a8250 100644 --- a/data_descriptors/standard_name/mass_fraction_of_chlorine_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_chlorine_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_chlorine_dioxide_in_air", + "id": "mass_fraction_of_chlorine_dioxide_in_air", "type": "standard_name", "name": "mass_fraction_of_chlorine_dioxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/mass_fraction_of_chlorine_monoxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_chlorine_monoxide_in_air.json index fab8e5206..571c6d909 100644 --- a/data_descriptors/standard_name/mass_fraction_of_chlorine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_chlorine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_chlorine_monoxide_in_air", + "id": "mass_fraction_of_chlorine_monoxide_in_air", "type": "standard_name", "name": "mass_fraction_of_chlorine_monoxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/mass_fraction_of_chlorine_nitrate_in_air.json b/data_descriptors/standard_name/mass_fraction_of_chlorine_nitrate_in_air.json index 45c54f83d..13c336d95 100644 --- a/data_descriptors/standard_name/mass_fraction_of_chlorine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_chlorine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_chlorine_nitrate_in_air", + "id": "mass_fraction_of_chlorine_nitrate_in_air", "type": "standard_name", "name": "mass_fraction_of_chlorine_nitrate_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_chlorophyll_a_in_sea_water.json b/data_descriptors/standard_name/mass_fraction_of_chlorophyll_a_in_sea_water.json index 4f29bcf53..18b62e548 100644 --- a/data_descriptors/standard_name/mass_fraction_of_chlorophyll_a_in_sea_water.json +++ b/data_descriptors/standard_name/mass_fraction_of_chlorophyll_a_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_chlorophyll_a_in_sea_water", + "id": "mass_fraction_of_chlorophyll_a_in_sea_water", "type": "standard_name", "name": "mass_fraction_of_chlorophyll_a_in_sea_water", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally; all contain a chlorin ring which gives the green pigment and a side chain whose structure varies. Chlorophyll-a is the most commonly occurring form of natural chlorophyll.", diff --git a/data_descriptors/standard_name/mass_fraction_of_clay_in_soil.json b/data_descriptors/standard_name/mass_fraction_of_clay_in_soil.json index 2d9e66219..b4af36adb 100644 --- a/data_descriptors/standard_name/mass_fraction_of_clay_in_soil.json +++ b/data_descriptors/standard_name/mass_fraction_of_clay_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_clay_in_soil", + "id": "mass_fraction_of_clay_in_soil", "type": "standard_name", "name": "mass_fraction_of_clay_in_soil", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the mass of X divided by the mass of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Grain-size class distribution is based on the Udden-Wentworth scale.", diff --git a/data_descriptors/standard_name/mass_fraction_of_cloud_condensed_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cloud_condensed_water_in_air.json index 223823f1d..303c011c3 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cloud_condensed_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cloud_condensed_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cloud_condensed_water_in_air", + "id": "mass_fraction_of_cloud_condensed_water_in_air", "type": "standard_name", "name": "mass_fraction_of_cloud_condensed_water_in_air", "description": "\"condensed_water\" means liquid and ice. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_cloud_ice_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cloud_ice_in_air.json index d399e774b..c0b74c8c0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cloud_ice_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cloud_ice_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cloud_ice_in_air", + "id": "mass_fraction_of_cloud_ice_in_air", "type": "standard_name", "name": "mass_fraction_of_cloud_ice_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_cloud_liquid_water_in_air.json index 82831b746..7f9e73e95 100644 --- a/data_descriptors/standard_name/mass_fraction_of_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_cloud_liquid_water_in_air", + "id": "mass_fraction_of_cloud_liquid_water_in_air", "type": "standard_name", "name": "mass_fraction_of_cloud_liquid_water_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/mass_fraction_of_clox_expressed_as_chlorine_in_air.json b/data_descriptors/standard_name/mass_fraction_of_clox_expressed_as_chlorine_in_air.json index fd996921e..aed75361b 100644 --- a/data_descriptors/standard_name/mass_fraction_of_clox_expressed_as_chlorine_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_clox_expressed_as_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_clox_expressed_as_chlorine_in_air", + "id": "mass_fraction_of_clox_expressed_as_chlorine_in_air", "type": "standard_name", "name": "mass_fraction_of_clox_expressed_as_chlorine_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_convective_cloud_condensed_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_convective_cloud_condensed_water_in_air.json index d216ef165..ceaa8c0c7 100644 --- a/data_descriptors/standard_name/mass_fraction_of_convective_cloud_condensed_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_convective_cloud_condensed_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_convective_cloud_condensed_water_in_air", + "id": "mass_fraction_of_convective_cloud_condensed_water_in_air", "type": "standard_name", "name": "mass_fraction_of_convective_cloud_condensed_water_in_air", "description": "\"condensed_water\" means liquid and ice. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_convective_cloud_ice_in_air.json b/data_descriptors/standard_name/mass_fraction_of_convective_cloud_ice_in_air.json index d3d973b47..c198c1178 100644 --- a/data_descriptors/standard_name/mass_fraction_of_convective_cloud_ice_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_convective_cloud_ice_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_convective_cloud_ice_in_air", + "id": "mass_fraction_of_convective_cloud_ice_in_air", "type": "standard_name", "name": "mass_fraction_of_convective_cloud_ice_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/mass_fraction_of_convective_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_convective_cloud_liquid_water_in_air.json index 78e7b7fa8..eb03a39b3 100644 --- a/data_descriptors/standard_name/mass_fraction_of_convective_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_convective_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_convective_cloud_liquid_water_in_air", + "id": "mass_fraction_of_convective_cloud_liquid_water_in_air", "type": "standard_name", "name": "mass_fraction_of_convective_cloud_liquid_water_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Convective cloud is that produced by the convection schemes in an atmosphere model. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/mass_fraction_of_dichlorine_peroxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_dichlorine_peroxide_in_air.json index e7500855e..d819f0196 100644 --- a/data_descriptors/standard_name/mass_fraction_of_dichlorine_peroxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_dichlorine_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_dichlorine_peroxide_in_air", + "id": "mass_fraction_of_dichlorine_peroxide_in_air", "type": "standard_name", "name": "mass_fraction_of_dichlorine_peroxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_dimethyl_sulfide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_dimethyl_sulfide_in_air.json index ba68c4a54..f7503fe59 100644 --- a/data_descriptors/standard_name/mass_fraction_of_dimethyl_sulfide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_dimethyl_sulfide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_dimethyl_sulfide_in_air", + "id": "mass_fraction_of_dimethyl_sulfide_in_air", "type": "standard_name", "name": "mass_fraction_of_dimethyl_sulfide_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_dinitrogen_pentoxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_dinitrogen_pentoxide_in_air.json index d9b747c1d..8eb46ad4e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_dinitrogen_pentoxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_dinitrogen_pentoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_dinitrogen_pentoxide_in_air", + "id": "mass_fraction_of_dinitrogen_pentoxide_in_air", "type": "standard_name", "name": "mass_fraction_of_dinitrogen_pentoxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/mass_fraction_of_dust_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_dust_dry_aerosol_particles_in_air.json index e057713a7..180947ea1 100644 --- a/data_descriptors/standard_name/mass_fraction_of_dust_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_dust_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_dust_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_dust_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_dust_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air.json index 943db4b47..d9bd482a8 100644 --- a/data_descriptors/standard_name/mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/mass_fraction_of_ethane_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ethane_in_air.json index e2899fd2a..1735b1a6a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ethane_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ethane_in_air", + "id": "mass_fraction_of_ethane_in_air", "type": "standard_name", "name": "mass_fraction_of_ethane_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_ethanol_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ethanol_in_air.json index 1afa2b92b..813f6e9e7 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ethanol_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ethanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ethanol_in_air", + "id": "mass_fraction_of_ethanol_in_air", "type": "standard_name", "name": "mass_fraction_of_ethanol_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/mass_fraction_of_ethene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ethene_in_air.json index 0a259ea77..0d62e9839 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ethene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ethene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ethene_in_air", + "id": "mass_fraction_of_ethene_in_air", "type": "standard_name", "name": "mass_fraction_of_ethene_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_ethyne_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ethyne_in_air.json index e3f590931..77a396fe4 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ethyne_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ethyne_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ethyne_in_air", + "id": "mass_fraction_of_ethyne_in_air", "type": "standard_name", "name": "mass_fraction_of_ethyne_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/mass_fraction_of_formaldehyde_in_air.json b/data_descriptors/standard_name/mass_fraction_of_formaldehyde_in_air.json index 6037080b1..0ac9599c0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_formaldehyde_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_formaldehyde_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_formaldehyde_in_air", + "id": "mass_fraction_of_formaldehyde_in_air", "type": "standard_name", "name": "mass_fraction_of_formaldehyde_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for formaldehyde is CH2O.", diff --git a/data_descriptors/standard_name/mass_fraction_of_formic_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_formic_acid_in_air.json index e91cb4657..c8d1def31 100644 --- a/data_descriptors/standard_name/mass_fraction_of_formic_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_formic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_formic_acid_in_air", + "id": "mass_fraction_of_formic_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_formic_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/mass_fraction_of_frozen_water_in_soil_moisture.json b/data_descriptors/standard_name/mass_fraction_of_frozen_water_in_soil_moisture.json index 0f5410e88..bba551a28 100644 --- a/data_descriptors/standard_name/mass_fraction_of_frozen_water_in_soil_moisture.json +++ b/data_descriptors/standard_name/mass_fraction_of_frozen_water_in_soil_moisture.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_frozen_water_in_soil_moisture", + "id": "mass_fraction_of_frozen_water_in_soil_moisture", "type": "standard_name", "name": "mass_fraction_of_frozen_water_in_soil_moisture", "description": "\"frozen_water\" means ice. \"moisture\" means water in all phases contained in soil. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_gaseous_divalent_mercury_in_air.json b/data_descriptors/standard_name/mass_fraction_of_gaseous_divalent_mercury_in_air.json index 9350a82f0..e52ce97e4 100644 --- a/data_descriptors/standard_name/mass_fraction_of_gaseous_divalent_mercury_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_gaseous_divalent_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_gaseous_divalent_mercury_in_air", + "id": "mass_fraction_of_gaseous_divalent_mercury_in_air", "type": "standard_name", "name": "mass_fraction_of_gaseous_divalent_mercury_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/mass_fraction_of_gaseous_elemental_mercury_in_air.json b/data_descriptors/standard_name/mass_fraction_of_gaseous_elemental_mercury_in_air.json index 86e965e3a..6aa9fe1a2 100644 --- a/data_descriptors/standard_name/mass_fraction_of_gaseous_elemental_mercury_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_gaseous_elemental_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_gaseous_elemental_mercury_in_air", + "id": "mass_fraction_of_gaseous_elemental_mercury_in_air", "type": "standard_name", "name": "mass_fraction_of_gaseous_elemental_mercury_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical symbol for mercury is Hg.", diff --git a/data_descriptors/standard_name/mass_fraction_of_graupel_and_hail_in_air.json b/data_descriptors/standard_name/mass_fraction_of_graupel_and_hail_in_air.json index e6f17f5ee..a46ccb4b2 100644 --- a/data_descriptors/standard_name/mass_fraction_of_graupel_and_hail_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_graupel_and_hail_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_graupel_and_hail_in_air", + "id": "mass_fraction_of_graupel_and_hail_in_air", "type": "standard_name", "name": "mass_fraction_of_graupel_and_hail_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel. For models that do distinguish between them, separate standard names for hail and graupel are available.", diff --git a/data_descriptors/standard_name/mass_fraction_of_graupel_in_air.json b/data_descriptors/standard_name/mass_fraction_of_graupel_in_air.json index 0d421ae14..0598ce82f 100644 --- a/data_descriptors/standard_name/mass_fraction_of_graupel_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_graupel_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_graupel_in_air", + "id": "mass_fraction_of_graupel_in_air", "type": "standard_name", "name": "mass_fraction_of_graupel_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. There are also separate standard names for hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/mass_fraction_of_gravel_in_soil.json b/data_descriptors/standard_name/mass_fraction_of_gravel_in_soil.json index d9a7ddcb8..7c345bd85 100644 --- a/data_descriptors/standard_name/mass_fraction_of_gravel_in_soil.json +++ b/data_descriptors/standard_name/mass_fraction_of_gravel_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_gravel_in_soil", + "id": "mass_fraction_of_gravel_in_soil", "type": "standard_name", "name": "mass_fraction_of_gravel_in_soil", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y'', where X is a material constituent of Y. It is evaluated as the mass of X divided by the mass of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Grain-size class distribution is based on the Udden-Wentworth scale.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hail_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hail_in_air.json index 162f4cf38..5f78b98ae 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hail_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hail_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hail_in_air", + "id": "mass_fraction_of_hail_in_air", "type": "standard_name", "name": "mass_fraction_of_hail_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). Hail is precipitation in the form of balls or irregular lumps of ice, often restricted by a size convention to diameters of 5 mm or more. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Hail. For diameters of less than 5 mm standard names for \"graupel\" should be used. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/mass_fraction_of_halon1202_in_air.json b/data_descriptors/standard_name/mass_fraction_of_halon1202_in_air.json index 5bcfe689c..2b6ebd15d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_halon1202_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_halon1202_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_halon1202_in_air", + "id": "mass_fraction_of_halon1202_in_air", "type": "standard_name", "name": "mass_fraction_of_halon1202_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_halon1211_in_air.json b/data_descriptors/standard_name/mass_fraction_of_halon1211_in_air.json index 0cad0504c..84ce46a21 100644 --- a/data_descriptors/standard_name/mass_fraction_of_halon1211_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_halon1211_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_halon1211_in_air", + "id": "mass_fraction_of_halon1211_in_air", "type": "standard_name", "name": "mass_fraction_of_halon1211_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_halon1301_in_air.json b/data_descriptors/standard_name/mass_fraction_of_halon1301_in_air.json index 33d0c80fb..73e36b0cf 100644 --- a/data_descriptors/standard_name/mass_fraction_of_halon1301_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_halon1301_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_halon1301_in_air", + "id": "mass_fraction_of_halon1301_in_air", "type": "standard_name", "name": "mass_fraction_of_halon1301_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_halon2402_in_air.json b/data_descriptors/standard_name/mass_fraction_of_halon2402_in_air.json index 979417c21..582db649d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_halon2402_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_halon2402_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_halon2402_in_air", + "id": "mass_fraction_of_halon2402_in_air", "type": "standard_name", "name": "mass_fraction_of_halon2402_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hcc140a_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hcc140a_in_air.json index 696766e6e..64411c635 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hcc140a_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hcc140a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hcc140a_in_air", + "id": "mass_fraction_of_hcc140a_in_air", "type": "standard_name", "name": "mass_fraction_of_hcc140a_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hcfc141b_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hcfc141b_in_air.json index 02491dad2..b664eb2c0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hcfc141b_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hcfc141b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hcfc141b_in_air", + "id": "mass_fraction_of_hcfc141b_in_air", "type": "standard_name", "name": "mass_fraction_of_hcfc141b_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hcfc142b_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hcfc142b_in_air.json index d03e101a0..dd5df5bd0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hcfc142b_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hcfc142b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hcfc142b_in_air", + "id": "mass_fraction_of_hcfc142b_in_air", "type": "standard_name", "name": "mass_fraction_of_hcfc142b_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hcfc22_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hcfc22_in_air.json index 74b01c35d..a8407319c 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hcfc22_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hcfc22_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hcfc22_in_air", + "id": "mass_fraction_of_hcfc22_in_air", "type": "standard_name", "name": "mass_fraction_of_hcfc22_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hexachlorobiphenyl_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hexachlorobiphenyl_in_air.json index 7b099b33e..892968aad 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hexachlorobiphenyl_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hexachlorobiphenyl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hexachlorobiphenyl_in_air", + "id": "mass_fraction_of_hexachlorobiphenyl_in_air", "type": "standard_name", "name": "mass_fraction_of_hexachlorobiphenyl_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hexachlorobiphenyl is C12H4Cl6. The structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hox_expressed_as_hydrogen_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hox_expressed_as_hydrogen_in_air.json index 1deeb75a5..6c677e5a2 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hox_expressed_as_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hox_expressed_as_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hox_expressed_as_hydrogen_in_air", + "id": "mass_fraction_of_hox_expressed_as_hydrogen_in_air", "type": "standard_name", "name": "mass_fraction_of_hox_expressed_as_hydrogen_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"HOx\" means a combination of two radical species containing hydrogen and oxygen, OH and HO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hydrogen_bromide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hydrogen_bromide_in_air.json index d148145f9..d0ff0c131 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hydrogen_bromide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hydrogen_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hydrogen_bromide_in_air", + "id": "mass_fraction_of_hydrogen_bromide_in_air", "type": "standard_name", "name": "mass_fraction_of_hydrogen_bromide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hydrogen_chloride_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hydrogen_chloride_in_air.json index d3d8da4a5..d3bf09ad9 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hydrogen_chloride_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hydrogen_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hydrogen_chloride_in_air", + "id": "mass_fraction_of_hydrogen_chloride_in_air", "type": "standard_name", "name": "mass_fraction_of_hydrogen_chloride_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hydrogen_cyanide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hydrogen_cyanide_in_air.json index 7bd8e0de5..4db7d3535 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hydrogen_cyanide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hydrogen_cyanide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hydrogen_cyanide_in_air", + "id": "mass_fraction_of_hydrogen_cyanide_in_air", "type": "standard_name", "name": "mass_fraction_of_hydrogen_cyanide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hydrogen_peroxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hydrogen_peroxide_in_air.json index 75af455dc..04d53384e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hydrogen_peroxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hydrogen_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hydrogen_peroxide_in_air", + "id": "mass_fraction_of_hydrogen_peroxide_in_air", "type": "standard_name", "name": "mass_fraction_of_hydrogen_peroxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hydroperoxyl_radical_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hydroperoxyl_radical_in_air.json index e3f410e3d..c112fd531 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hydroperoxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hydroperoxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hydroperoxyl_radical_in_air", + "id": "mass_fraction_of_hydroperoxyl_radical_in_air", "type": "standard_name", "name": "mass_fraction_of_hydroperoxyl_radical_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for the hydroperoxyl radical is HO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hydroxyl_radical_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hydroxyl_radical_in_air.json index 843f77397..ee60898fc 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hydroxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hydroxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hydroxyl_radical_in_air", + "id": "mass_fraction_of_hydroxyl_radical_in_air", "type": "standard_name", "name": "mass_fraction_of_hydroxyl_radical_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived,species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hypobromous_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hypobromous_acid_in_air.json index 2f19d7d7c..819265086 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hypobromous_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hypobromous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hypobromous_acid_in_air", + "id": "mass_fraction_of_hypobromous_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_hypobromous_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/mass_fraction_of_hypochlorous_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_hypochlorous_acid_in_air.json index 46413dc1d..2d2185c95 100644 --- a/data_descriptors/standard_name/mass_fraction_of_hypochlorous_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_hypochlorous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_hypochlorous_acid_in_air", + "id": "mass_fraction_of_hypochlorous_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_hypochlorous_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/mass_fraction_of_inorganic_bromine_in_air.json b/data_descriptors/standard_name/mass_fraction_of_inorganic_bromine_in_air.json index 5fd0f4d4f..d33654f68 100644 --- a/data_descriptors/standard_name/mass_fraction_of_inorganic_bromine_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_inorganic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_inorganic_bromine_in_air", + "id": "mass_fraction_of_inorganic_bromine_in_air", "type": "standard_name", "name": "mass_fraction_of_inorganic_bromine_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_inorganic_chlorine_in_air.json b/data_descriptors/standard_name/mass_fraction_of_inorganic_chlorine_in_air.json index 6b9d75d7d..7da4910d9 100644 --- a/data_descriptors/standard_name/mass_fraction_of_inorganic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_inorganic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_inorganic_chlorine_in_air", + "id": "mass_fraction_of_inorganic_chlorine_in_air", "type": "standard_name", "name": "mass_fraction_of_inorganic_chlorine_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. \"Inorganic chlorine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"clox\" are used for quantities that contain all inorganic chlorine species except HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_isoprene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_isoprene_in_air.json index 1b753665d..83a56dde2 100644 --- a/data_descriptors/standard_name/mass_fraction_of_isoprene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_isoprene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_isoprene_in_air", + "id": "mass_fraction_of_isoprene_in_air", "type": "standard_name", "name": "mass_fraction_of_isoprene_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_limonene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_limonene_in_air.json index 7baa45194..8f8ab13a7 100644 --- a/data_descriptors/standard_name/mass_fraction_of_limonene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_limonene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_limonene_in_air", + "id": "mass_fraction_of_limonene_in_air", "type": "standard_name", "name": "mass_fraction_of_limonene_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_liquid_precipitation_in_air.json b/data_descriptors/standard_name/mass_fraction_of_liquid_precipitation_in_air.json index 24fe461d1..228726c60 100644 --- a/data_descriptors/standard_name/mass_fraction_of_liquid_precipitation_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_liquid_precipitation_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_liquid_precipitation_in_air", + "id": "mass_fraction_of_liquid_precipitation_in_air", "type": "standard_name", "name": "mass_fraction_of_liquid_precipitation_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Liquid_precipitation\" includes both \"rain\" and \"drizzle\". \"Rain\" means drops of water falling through the atmosphere that have a diameter greater than 0.5 mm. \"Drizzle\" means drops of water falling through the atmosphere that have a diameter typically in the range 0.2-0.5 mm.", diff --git a/data_descriptors/standard_name/mass_fraction_of_mercury_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_mercury_dry_aerosol_particles_in_air.json index 9b944a020..5a7d064f9 100644 --- a/data_descriptors/standard_name/mass_fraction_of_mercury_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_mercury_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_mercury_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_mercury_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_mercury_dry_aerosol_particles_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methane_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methane_in_air.json index d4e021b89..a9a202ad1 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methane_in_air", + "id": "mass_fraction_of_methane_in_air", "type": "standard_name", "name": "mass_fraction_of_methane_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air.json index bfd2f42bf..b1d394fa3 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_methanesulfonic_acid_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for methanesulfonic acid is CH3SO3H.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methanol_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methanol_in_air.json index 873ec9846..8c7c934c6 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methanol_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methanol_in_air", + "id": "mass_fraction_of_methanol_in_air", "type": "standard_name", "name": "mass_fraction_of_methanol_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethanol is C2H5OH. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methyl_bromide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methyl_bromide_in_air.json index 5f4684096..0cec0f8ab 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methyl_bromide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methyl_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methyl_bromide_in_air", + "id": "mass_fraction_of_methyl_bromide_in_air", "type": "standard_name", "name": "mass_fraction_of_methyl_bromide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methyl_chloride_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methyl_chloride_in_air.json index 852172250..c8432adf8 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methyl_chloride_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methyl_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methyl_chloride_in_air", + "id": "mass_fraction_of_methyl_chloride_in_air", "type": "standard_name", "name": "mass_fraction_of_methyl_chloride_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methyl_hydroperoxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methyl_hydroperoxide_in_air.json index b6c0cd97e..52bec038a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methyl_hydroperoxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methyl_hydroperoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methyl_hydroperoxide_in_air", + "id": "mass_fraction_of_methyl_hydroperoxide_in_air", "type": "standard_name", "name": "mass_fraction_of_methyl_hydroperoxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/mass_fraction_of_methyl_peroxy_radical_in_air.json b/data_descriptors/standard_name/mass_fraction_of_methyl_peroxy_radical_in_air.json index ac132777b..feaecf22f 100644 --- a/data_descriptors/standard_name/mass_fraction_of_methyl_peroxy_radical_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_methyl_peroxy_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_methyl_peroxy_radical_in_air", + "id": "mass_fraction_of_methyl_peroxy_radical_in_air", "type": "standard_name", "name": "mass_fraction_of_methyl_peroxy_radical_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl_peroxy_radical is CH3O2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_molecular_hydrogen_in_air.json b/data_descriptors/standard_name/mass_fraction_of_molecular_hydrogen_in_air.json index 8a69ea85b..2fcd74bd1 100644 --- a/data_descriptors/standard_name/mass_fraction_of_molecular_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_molecular_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_molecular_hydrogen_in_air", + "id": "mass_fraction_of_molecular_hydrogen_in_air", "type": "standard_name", "name": "mass_fraction_of_molecular_hydrogen_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitrate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitrate_dry_aerosol_particles_in_air.json index 91fc385d1..dcba187aa 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitrate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitrate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitrate_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_nitrate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_nitrate_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Mass_fraction_of_nitrate\" means that the mass is expressed as mass of NO3. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitrate_radical_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitrate_radical_in_air.json index fd80e5aa4..88219f07e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitrate_radical_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitrate_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitrate_radical_in_air", + "id": "mass_fraction_of_nitrate_radical_in_air", "type": "standard_name", "name": "mass_fraction_of_nitrate_radical_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitric_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitric_acid_in_air.json index b409c2b79..5f500a236 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitric_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitric_acid_in_air", + "id": "mass_fraction_of_nitric_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_nitric_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json index fc58b362a..334244093 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The chemical formula for nitric acid is HNO3. Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitrogen_dioxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitrogen_dioxide_in_air.json index b02d9a2c7..28c994ea9 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitrogen_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitrogen_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitrogen_dioxide_in_air", + "id": "mass_fraction_of_nitrogen_dioxide_in_air", "type": "standard_name", "name": "mass_fraction_of_nitrogen_dioxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitrogen_monoxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitrogen_monoxide_in_air.json index eb9b7ba12..fb17c8238 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitrogen_monoxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitrogen_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitrogen_monoxide_in_air", + "id": "mass_fraction_of_nitrogen_monoxide_in_air", "type": "standard_name", "name": "mass_fraction_of_nitrogen_monoxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitrous_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitrous_acid_in_air.json index 8038bc737..b15500f63 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitrous_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitrous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitrous_acid_in_air", + "id": "mass_fraction_of_nitrous_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_nitrous_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nitrous_oxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nitrous_oxide_in_air.json index af0ba0274..4ae0ee7dd 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nitrous_oxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nitrous_oxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nitrous_oxide_in_air", + "id": "mass_fraction_of_nitrous_oxide_in_air", "type": "standard_name", "name": "mass_fraction_of_nitrous_oxide_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nmvoc_expressed_as_carbon_in_air.json index dd4c94f21..688fa54da 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nmvoc_expressed_as_carbon_in_air", + "id": "mass_fraction_of_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_fraction_of_nmvoc_expressed_as_carbon_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_fraction_of_nox_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mass_fraction_of_nox_expressed_as_nitrogen_in_air.json index f6a946bcc..3c6e3f669 100644 --- a/data_descriptors/standard_name/mass_fraction_of_nox_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_nox_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_nox_expressed_as_nitrogen_in_air", + "id": "mass_fraction_of_nox_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mass_fraction_of_nox_expressed_as_nitrogen_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The term \"peroxy_radicals\" means all organic and inorganic peroxy radicals. This includes HO2 and all organic peroxy radicals, sometimes referred to as RO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_noy_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mass_fraction_of_noy_expressed_as_nitrogen_in_air.json index ad6602633..4ec134f29 100644 --- a/data_descriptors/standard_name/mass_fraction_of_noy_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_noy_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_noy_expressed_as_nitrogen_in_air", + "id": "mass_fraction_of_noy_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mass_fraction_of_noy_expressed_as_nitrogen_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_fraction_of_organic_matter_in_soil.json b/data_descriptors/standard_name/mass_fraction_of_organic_matter_in_soil.json index d51b274e5..f111ae373 100644 --- a/data_descriptors/standard_name/mass_fraction_of_organic_matter_in_soil.json +++ b/data_descriptors/standard_name/mass_fraction_of_organic_matter_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_organic_matter_in_soil", + "id": "mass_fraction_of_organic_matter_in_soil", "type": "standard_name", "name": "mass_fraction_of_organic_matter_in_soil", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the mass of X divided by the mass of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/mass_fraction_of_oxygenated_hydrocarbons_in_air.json b/data_descriptors/standard_name/mass_fraction_of_oxygenated_hydrocarbons_in_air.json index b8f268a39..08065fd50 100644 --- a/data_descriptors/standard_name/mass_fraction_of_oxygenated_hydrocarbons_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_oxygenated_hydrocarbons_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_oxygenated_hydrocarbons_in_air", + "id": "mass_fraction_of_oxygenated_hydrocarbons_in_air", "type": "standard_name", "name": "mass_fraction_of_oxygenated_hydrocarbons_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Oxygenated\" means containing oxygen. \"Hydrocarbon\" means a compound containing hydrogen and carbon.", diff --git a/data_descriptors/standard_name/mass_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/mass_fraction_of_ozone_in_air.json index e2dbc3223..4e7391250 100644 --- a/data_descriptors/standard_name/mass_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_ozone_in_air", + "id": "mass_fraction_of_ozone_in_air", "type": "standard_name", "name": "mass_fraction_of_ozone_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json index 7f3b2cff1..7c185ef80 100644 --- a/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", + "id": "mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air.json index c21e89695..eea7a9055 100644 --- a/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_peroxy_radicals_in_air.json b/data_descriptors/standard_name/mass_fraction_of_peroxy_radicals_in_air.json index 1248e0136..a29b9a899 100644 --- a/data_descriptors/standard_name/mass_fraction_of_peroxy_radicals_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_peroxy_radicals_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_peroxy_radicals_in_air", + "id": "mass_fraction_of_peroxy_radicals_in_air", "type": "standard_name", "name": "mass_fraction_of_peroxy_radicals_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The term \"peroxy_radicals\" means all organic and inorganic peroxy radicals. This includes HO2 and all organic peroxy radicals, sometimes referred to as RO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_peroxyacetyl_nitrate_in_air.json b/data_descriptors/standard_name/mass_fraction_of_peroxyacetyl_nitrate_in_air.json index b6e353f16..327c5fa9b 100644 --- a/data_descriptors/standard_name/mass_fraction_of_peroxyacetyl_nitrate_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_peroxyacetyl_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_peroxyacetyl_nitrate_in_air", + "id": "mass_fraction_of_peroxyacetyl_nitrate_in_air", "type": "standard_name", "name": "mass_fraction_of_peroxyacetyl_nitrate_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/mass_fraction_of_peroxynitric_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_peroxynitric_acid_in_air.json index 3b8d573de..a2e5b8899 100644 --- a/data_descriptors/standard_name/mass_fraction_of_peroxynitric_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_peroxynitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_peroxynitric_acid_in_air", + "id": "mass_fraction_of_peroxynitric_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_peroxynitric_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_ambient_aerosol_particles_in_air.json index 42dd76c46..a9a332fe5 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_ambient_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of \"relative_humidity\" and \"air_temperature.\"", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air.json index a9fc1d349..7b36f2dc0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_ammonium_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for ammonium is NH4.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_dry_aerosol_particles_in_air.json index 45a2e434e..f1b784d5b 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air.json index d7fec9f3f..a944cc9cf 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_dust_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air.json index d9cd2cec0..780c081bc 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_elemental_carbon_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air.json index a76f850e4..2e97d4e56 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_nitrate_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json index afbaa7aa4..39feadb5b 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", + "id": "mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air.json index 539ff9bf6..62ee85888 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json index c6eafd506..1dbe7f503 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Primary particulate organic matter\" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json index ef1cde93d..549122354 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", + "id": "mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air.json index bf4f9b41f..bb07af31d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_sea_salt_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air.json index 40d2abbba..cd4bbb50a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm10_sulfate_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm1_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm1_ambient_aerosol_particles_in_air.json index 1bb99fe4a..4732a14bb 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm1_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm1_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm1_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_pm1_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm1_ambient_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm1_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm1_dry_aerosol_particles_in_air.json index 5e0b1a7e9..1661b1ba2 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm1_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm1_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm1_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm1_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm1_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm1 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometer.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air.json index 7c9ed33fa..b065896fd 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air.json index 6599d1663..3a356b294 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_ammonium_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The chemical formula for ammonium is NH4.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_dry_aerosol_particles_in_air.json index d4871db97..2cad787a5 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air.json index a3c3d9619..1897a9ffd 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_dust_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air.json index e4d6659a4..bc6f00fe5 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_elemental_carbon_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air.json index f0d63a3ad..41d5a4a8c 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_nitrate_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json index e77b54d07..43e1371c5 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", + "id": "mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air.json index 370489596..9df509b83 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json index 0a49e1ef5..9b07b1cfa 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Primary particulate organic matter\" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json index 9e57d38ee..c41be6fa8 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", + "id": "mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json index 4d20859cb..a8c113812 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_sea_salt_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air.json index 627ad973e..f606615c5 100644 --- a/data_descriptors/standard_name/mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_pm2p5_sulfate_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/mass_fraction_of_precipitation_in_air.json b/data_descriptors/standard_name/mass_fraction_of_precipitation_in_air.json index a3bd6fac1..481a36aec 100644 --- a/data_descriptors/standard_name/mass_fraction_of_precipitation_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_precipitation_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_precipitation_in_air", + "id": "mass_fraction_of_precipitation_in_air", "type": "standard_name", "name": "mass_fraction_of_precipitation_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases.", diff --git a/data_descriptors/standard_name/mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json index 01951d5a9..a1f4cdae4 100644 --- a/data_descriptors/standard_name/mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Primary particulate organic matter \" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_propane_in_air.json b/data_descriptors/standard_name/mass_fraction_of_propane_in_air.json index 9b381cc0c..0f3b8933f 100644 --- a/data_descriptors/standard_name/mass_fraction_of_propane_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_propane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_propane_in_air", + "id": "mass_fraction_of_propane_in_air", "type": "standard_name", "name": "mass_fraction_of_propane_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_propene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_propene_in_air.json index 3b58beeca..af449814c 100644 --- a/data_descriptors/standard_name/mass_fraction_of_propene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_propene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_propene_in_air", + "id": "mass_fraction_of_propene_in_air", "type": "standard_name", "name": "mass_fraction_of_propene_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mass_fraction_of_radon_in_air.json b/data_descriptors/standard_name/mass_fraction_of_radon_in_air.json index b0103e9c0..a5753663d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_radon_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_radon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_radon_in_air", + "id": "mass_fraction_of_radon_in_air", "type": "standard_name", "name": "mass_fraction_of_radon_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/mass_fraction_of_rainfall_falling_onto_surface_snow.json b/data_descriptors/standard_name/mass_fraction_of_rainfall_falling_onto_surface_snow.json index cabdd13bb..8d2208575 100644 --- a/data_descriptors/standard_name/mass_fraction_of_rainfall_falling_onto_surface_snow.json +++ b/data_descriptors/standard_name/mass_fraction_of_rainfall_falling_onto_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_rainfall_falling_onto_surface_snow", + "id": "mass_fraction_of_rainfall_falling_onto_surface_snow", "type": "standard_name", "name": "mass_fraction_of_rainfall_falling_onto_surface_snow", "description": "The quantity with standard name mass_fraction_of_rainfall_falling_onto_surface_snow is the mass of rainfall falling onto snow as a fraction of the mass of rainfall falling within the area of interest. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The surface called \"surface\" means the lower boundary of the atmosphere. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/mass_fraction_of_sand_in_soil.json b/data_descriptors/standard_name/mass_fraction_of_sand_in_soil.json index 5dc161f43..c8680e860 100644 --- a/data_descriptors/standard_name/mass_fraction_of_sand_in_soil.json +++ b/data_descriptors/standard_name/mass_fraction_of_sand_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_sand_in_soil", + "id": "mass_fraction_of_sand_in_soil", "type": "standard_name", "name": "mass_fraction_of_sand_in_soil", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y'', where X is a material constituent of Y. It is evaluated as the mass of X divided by the mass of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Grain-size class distribution is based on the Udden-Wentworth scale.", diff --git a/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json b/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json index b53085575..e49f7fc59 100644 --- a/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", + "id": "mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "type": "standard_name", "name": "mass_fraction_of_sea_salt_dry_aerosol_particles_expressed_as_cations_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The phrase \"sea_salt_cation\" is the term used in standard names to describe collectively the group of cationic species that occur in sea salt. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Sea salt cations are mainly sodium (Na+), but also include potassium (K+), magnesium (Mg2+), calcium (Ca2+) and rarer cations. Where possible, the data variable should be accompanied by a complete description of the ions represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_in_air.json index 4c396cbcb..fc549052a 100644 --- a/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_sea_salt_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_sea_salt_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_sea_salt_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json index 197a22679..10f0fef5c 100644 --- a/data_descriptors/standard_name/mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Secondary particulate organic matter\" means particulate organic matter formed within the atmosphere from gaseous precursors. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/mass_fraction_of_shallow_convective_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_shallow_convective_cloud_liquid_water_in_air.json index e569ad788..aa163efff 100644 --- a/data_descriptors/standard_name/mass_fraction_of_shallow_convective_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_shallow_convective_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_shallow_convective_cloud_liquid_water_in_air", + "id": "mass_fraction_of_shallow_convective_cloud_liquid_water_in_air", "type": "standard_name", "name": "mass_fraction_of_shallow_convective_cloud_liquid_water_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Shallow convective cloud is nonprecipitating cumulus cloud with a cloud top below 3000m above the surface produced by the convection schemes in an atmosphere model. Some atmosphere models differentiate between shallow and deep convection. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/mass_fraction_of_silt_in_soil.json b/data_descriptors/standard_name/mass_fraction_of_silt_in_soil.json index 9fc5455f1..34f0e1c4e 100644 --- a/data_descriptors/standard_name/mass_fraction_of_silt_in_soil.json +++ b/data_descriptors/standard_name/mass_fraction_of_silt_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_silt_in_soil", + "id": "mass_fraction_of_silt_in_soil", "type": "standard_name", "name": "mass_fraction_of_silt_in_soil", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y'', where X is a material constituent of Y. It is evaluated as the mass of X divided by the mass of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Grain-size class distribution is based on the Udden-Wentworth scale.", diff --git a/data_descriptors/standard_name/mass_fraction_of_snow_in_air.json b/data_descriptors/standard_name/mass_fraction_of_snow_in_air.json index ac60d5810..a29fe0ead 100644 --- a/data_descriptors/standard_name/mass_fraction_of_snow_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_snow_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_snow_in_air", + "id": "mass_fraction_of_snow_in_air", "type": "standard_name", "name": "mass_fraction_of_snow_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Snow\" refers to the precipitating part of snow in the atmosphere \u2013 the cloud snow content is excluded.", diff --git a/data_descriptors/standard_name/mass_fraction_of_solid_precipitation_falling_onto_surface_snow.json b/data_descriptors/standard_name/mass_fraction_of_solid_precipitation_falling_onto_surface_snow.json index 09950213d..bcf8defbb 100644 --- a/data_descriptors/standard_name/mass_fraction_of_solid_precipitation_falling_onto_surface_snow.json +++ b/data_descriptors/standard_name/mass_fraction_of_solid_precipitation_falling_onto_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_solid_precipitation_falling_onto_surface_snow", + "id": "mass_fraction_of_solid_precipitation_falling_onto_surface_snow", "type": "standard_name", "name": "mass_fraction_of_solid_precipitation_falling_onto_surface_snow", "description": "The quantity with standard name mass_fraction_of_solid_precipitation_falling_onto_surface_snow is the mass of solid precipitation falling onto snow as a fraction of the mass of solid precipitation falling within the area of interest. Solid precipitation refers to the precipitation of water in the solid phase. Water in the atmosphere exists in one of three phases: solid, liquid or vapor. The solid phase can exist as snow, hail, graupel, cloud ice, or as a component of aerosol. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_ice_in_air.json b/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_ice_in_air.json index fef3ce7a6..a097ed048 100644 --- a/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_ice_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_ice_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_stratiform_cloud_ice_in_air", + "id": "mass_fraction_of_stratiform_cloud_ice_in_air", "type": "standard_name", "name": "mass_fraction_of_stratiform_cloud_ice_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", diff --git a/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_liquid_water_in_air.json index d18fa0649..484637be0 100644 --- a/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_stratiform_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_stratiform_cloud_liquid_water_in_air", + "id": "mass_fraction_of_stratiform_cloud_liquid_water_in_air", "type": "standard_name", "name": "mass_fraction_of_stratiform_cloud_liquid_water_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/mass_fraction_of_sulfate_dry_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_sulfate_dry_aerosol_particles_in_air.json index af12c6734..fc9eb3823 100644 --- a/data_descriptors/standard_name/mass_fraction_of_sulfate_dry_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_sulfate_dry_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_sulfate_dry_aerosol_particles_in_air", + "id": "mass_fraction_of_sulfate_dry_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_sulfate_dry_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Mass_fraction_of_sulfate\" means that the mass is expressed as mass of SO4. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake.", diff --git a/data_descriptors/standard_name/mass_fraction_of_sulfur_dioxide_in_air.json b/data_descriptors/standard_name/mass_fraction_of_sulfur_dioxide_in_air.json index d3011c3f6..97475d402 100644 --- a/data_descriptors/standard_name/mass_fraction_of_sulfur_dioxide_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_sulfur_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_sulfur_dioxide_in_air", + "id": "mass_fraction_of_sulfur_dioxide_in_air", "type": "standard_name", "name": "mass_fraction_of_sulfur_dioxide_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_sulfuric_acid_in_air.json b/data_descriptors/standard_name/mass_fraction_of_sulfuric_acid_in_air.json index 5b0e969cc..2a31594a5 100644 --- a/data_descriptors/standard_name/mass_fraction_of_sulfuric_acid_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_sulfuric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_sulfuric_acid_in_air", + "id": "mass_fraction_of_sulfuric_acid_in_air", "type": "standard_name", "name": "mass_fraction_of_sulfuric_acid_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for sulfuric acid is H2SO4.", diff --git a/data_descriptors/standard_name/mass_fraction_of_terpenes_in_air.json b/data_descriptors/standard_name/mass_fraction_of_terpenes_in_air.json index 708b7066d..a01662f8c 100644 --- a/data_descriptors/standard_name/mass_fraction_of_terpenes_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_terpenes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_terpenes_in_air", + "id": "mass_fraction_of_terpenes_in_air", "type": "standard_name", "name": "mass_fraction_of_terpenes_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Terpenes are hydrocarbons, that is,they contain only hydrogen and carbon combined in the general proportions (C5H8)n where n is an integer greater than or equal to one. The term \"terpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual terpene species, e.g., isoprene and limonene.", diff --git a/data_descriptors/standard_name/mass_fraction_of_toluene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_toluene_in_air.json index 71e081d32..7b93d0034 100644 --- a/data_descriptors/standard_name/mass_fraction_of_toluene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_toluene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_toluene_in_air", + "id": "mass_fraction_of_toluene_in_air", "type": "standard_name", "name": "mass_fraction_of_toluene_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/mass_fraction_of_unfrozen_water_in_soil_moisture.json b/data_descriptors/standard_name/mass_fraction_of_unfrozen_water_in_soil_moisture.json index 90bb6f491..b7a521cbd 100644 --- a/data_descriptors/standard_name/mass_fraction_of_unfrozen_water_in_soil_moisture.json +++ b/data_descriptors/standard_name/mass_fraction_of_unfrozen_water_in_soil_moisture.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_unfrozen_water_in_soil_moisture", + "id": "mass_fraction_of_unfrozen_water_in_soil_moisture", "type": "standard_name", "name": "mass_fraction_of_unfrozen_water_in_soil_moisture", "description": "\"moisture\" means water in all phases contained in soil. \"unfrozen_water\" means liquid and vapour. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_water_in_air.json b/data_descriptors/standard_name/mass_fraction_of_water_in_air.json index c1e57f470..f249c819d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_water_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_water_in_air", + "id": "mass_fraction_of_water_in_air", "type": "standard_name", "name": "mass_fraction_of_water_in_air", "description": "\"Water\" means water in all phases. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/mass_fraction_of_water_in_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_water_in_ambient_aerosol_particles_in_air.json index 49405348a..25ba76ef3 100644 --- a/data_descriptors/standard_name/mass_fraction_of_water_in_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_water_in_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_water_in_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_water_in_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_water_in_ambient_aerosol_particles_in_air", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles.", diff --git a/data_descriptors/standard_name/mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air.json index dea07d88b..d6e29cd5d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_water_in_pm10_ambient_aerosol_particles_in_air", "description": "\"Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air.json index cc92d8e46..2b94a0765 100644 --- a/data_descriptors/standard_name/mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air", + "id": "mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mass_fraction_of_water_in_pm2p5_ambient_aerosol_particles_in_air", "description": "Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/mass_fraction_of_xylene_in_air.json b/data_descriptors/standard_name/mass_fraction_of_xylene_in_air.json index b4c25a9b0..11e3d782d 100644 --- a/data_descriptors/standard_name/mass_fraction_of_xylene_in_air.json +++ b/data_descriptors/standard_name/mass_fraction_of_xylene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_fraction_of_xylene_in_air", + "id": "mass_fraction_of_xylene_in_air", "type": "standard_name", "name": "mass_fraction_of_xylene_in_air", "description": "\"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/mass_ratio_of_moisture_to_dry_soil.json b/data_descriptors/standard_name/mass_ratio_of_moisture_to_dry_soil.json index a2d013596..e89a6d225 100644 --- a/data_descriptors/standard_name/mass_ratio_of_moisture_to_dry_soil.json +++ b/data_descriptors/standard_name/mass_ratio_of_moisture_to_dry_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mass_ratio_of_moisture_to_dry_soil", + "id": "mass_ratio_of_moisture_to_dry_soil", "type": "standard_name", "name": "mass_ratio_of_moisture_to_dry_soil", "description": "The quantity with standard name mass_ratio_of_moisture_to_dry_soil is also known as the water content of a soil or the wet-basis gravimetric moisture content. It is the ratio of the mass of water (liquid and solid) to the mass of the dried sample. The phrase \"ratio_of_X_to_Y\" means X/Y. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate.json b/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate.json index 056ff37e0..eec481056 100644 --- a/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate.json +++ b/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate", + "id": "maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate", "type": "standard_name", "name": "maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. Axial strain is the symmetric component of the tensor representing the gradient of internal forces (e.g. in ice). Strain rate refers to off-diagonal element(s) of the strain tensor (a single element for horizontal shear strain). \"Horizontal\" refers to the local horizontal in the location of the sea ice, i.e., perpendicular to the local gravity vector. Each of the strain components is defined with respect to a frame of reference. \"Coordinate rotation\" refers to the range of all possible orientations of the frame of reference. The shear strain has a maximum value relative to one of these orientations. The second invariant of strain rate, often referred to as the maximum shear strain [rate], is the maximum over coordinate rotations of the shear strain rate.", diff --git a/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress.json b/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress.json index 016d0ad61..b3a78bd67 100644 --- a/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress.json +++ b/data_descriptors/standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress", + "id": "maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress", "type": "standard_name", "name": "maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. Axial stress is the symmetric component of the tensor representing the gradient of internal forces (e.g. in ice). Shear stress refers to off-diagonal element(s) of the stress tensor (a single element for horizontal shear stress). \"Horizontal\" refers to the local horizontal in the location of the sea ice, i.e., perpendicular to the local gravity vector. Each of the stress components is defined with respect to a frame of reference. \"Coordinate rotation\" refers to the range of all possible orientations of the frame of reference. The shear stress has a maximum value relative to one of these orientations. The second invariant of stress, often referred to as the maximum shear stress, is the maximum over coordinate rotations of the shear stress.", diff --git a/data_descriptors/standard_name/medium_soil_pool_mass_content_of_carbon.json b/data_descriptors/standard_name/medium_soil_pool_mass_content_of_carbon.json index f98bf1d53..8e000ae37 100644 --- a/data_descriptors/standard_name/medium_soil_pool_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/medium_soil_pool_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/medium_soil_pool_mass_content_of_carbon", + "id": "medium_soil_pool_mass_content_of_carbon", "type": "standard_name", "name": "medium_soil_pool_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used. Soil carbon is returned to the atmosphere as the organic matter decays. The decay process takes varying amounts of time depending on the composition of the organic matter, the temperature and the availability of moisture. A carbon \"soil pool\" means the carbon contained in organic matter which has a characteristic period over which it decays and releases carbon into the atmosphere. \"Medium soil pool\" refers to the decay of organic matter in soil with a characteristic period of between ten and one hundred years under reference climate conditions of a temperature of 20 degrees Celsius and no water limitations.", diff --git a/data_descriptors/standard_name/medium_type_cloud_area_fraction.json b/data_descriptors/standard_name/medium_type_cloud_area_fraction.json index 573db10ba..15f563098 100644 --- a/data_descriptors/standard_name/medium_type_cloud_area_fraction.json +++ b/data_descriptors/standard_name/medium_type_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/medium_type_cloud_area_fraction", + "id": "medium_type_cloud_area_fraction", "type": "standard_name", "name": "medium_type_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Middle type clouds are: Altostratus, Altocumulus, Nimbostratus. X_type_cloud_area_fraction is generally determined on the basis of cloud type, though Numerical Weather Prediction (NWP) models often calculate them based on the vertical location of the cloud. For the cloud area fraction between specified levels in the atmosphere, standard names including \"cloud_area_fraction_in_atmosphere_layer\" are used. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/minimum_depth_of_aragonite_undersaturation_in_sea_water.json b/data_descriptors/standard_name/minimum_depth_of_aragonite_undersaturation_in_sea_water.json index e2a5c2641..e051e88bd 100644 --- a/data_descriptors/standard_name/minimum_depth_of_aragonite_undersaturation_in_sea_water.json +++ b/data_descriptors/standard_name/minimum_depth_of_aragonite_undersaturation_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minimum_depth_of_aragonite_undersaturation_in_sea_water", + "id": "minimum_depth_of_aragonite_undersaturation_in_sea_water", "type": "standard_name", "name": "minimum_depth_of_aragonite_undersaturation_in_sea_water", "description": "Depth is the vertical distance below the surface. 'Undersaturation' means that a solution is unsaturated with respect to a solute. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate. The \"minimum depth of undersaturation\", sometimes called the \"saturation horizon\", is the shallowest depth at which a body of water is an undersaturated solution of a named solute.", diff --git a/data_descriptors/standard_name/minimum_depth_of_calcite_undersaturation_in_sea_water.json b/data_descriptors/standard_name/minimum_depth_of_calcite_undersaturation_in_sea_water.json index 9edade728..0cff619fd 100644 --- a/data_descriptors/standard_name/minimum_depth_of_calcite_undersaturation_in_sea_water.json +++ b/data_descriptors/standard_name/minimum_depth_of_calcite_undersaturation_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minimum_depth_of_calcite_undersaturation_in_sea_water", + "id": "minimum_depth_of_calcite_undersaturation_in_sea_water", "type": "standard_name", "name": "minimum_depth_of_calcite_undersaturation_in_sea_water", "description": "Depth is the vertical distance below the surface. 'Undersaturation' means that a solution is unsaturated with respect to a solute. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate. The \"minimum depth of undersaturation\", sometimes called the \"saturation horizon\", is the shallowest depth at which a body of water is an undersaturated solution of a named solute.", diff --git a/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior.json b/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior.json index fbb599c5a..a1d8b4be8 100644 --- a/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior.json +++ b/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior", + "id": "minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior", "type": "standard_name", "name": "minimum_mass_ratio_of_water_to_dry_soil_for_soil_plastic_behavior", "description": "The phrase \"ratio_of_X_to_Y\" means X/Y. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. It is the lower limit of the water content at which a 3 mm diameter cylindrical soil sample will break in 3 to 10 mm pieces. It is the lower limit of the plastic state, which has the liquid limit as the upper bound. Known as the plastic limit.", diff --git a/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow.json b/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow.json index 519d9f938..a6639afc3 100644 --- a/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow.json +++ b/data_descriptors/standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow", + "id": "minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow", "type": "standard_name", "name": "minimum_mass_ratio_of_water_to_dry_soil_for_soil_viscous_flow", "description": "The phrase \"ratio_of_X_to_Y\" means X/Y. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. It is the lower limit of the water content at which a soil sample will flow in a viscous manner. Known as the liquid limit.", diff --git a/data_descriptors/standard_name/minus_one_times_surface_upwelling_longwave_flux_in_air.json b/data_descriptors/standard_name/minus_one_times_surface_upwelling_longwave_flux_in_air.json index b658fe2e6..5250cd507 100644 --- a/data_descriptors/standard_name/minus_one_times_surface_upwelling_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/minus_one_times_surface_upwelling_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_one_times_surface_upwelling_longwave_flux_in_air", + "id": "minus_one_times_surface_upwelling_longwave_flux_in_air", "type": "standard_name", "name": "minus_one_times_surface_upwelling_longwave_flux_in_air", "description": "The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Minus one times\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. The surface called \"surface\" means the lower boundary of the atmosphere. The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/minus_one_times_surface_upwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/minus_one_times_surface_upwelling_shortwave_flux_in_air.json index 9b2d4452b..fb007b2d0 100644 --- a/data_descriptors/standard_name/minus_one_times_surface_upwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/minus_one_times_surface_upwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_one_times_surface_upwelling_shortwave_flux_in_air", + "id": "minus_one_times_surface_upwelling_shortwave_flux_in_air", "type": "standard_name", "name": "minus_one_times_surface_upwelling_shortwave_flux_in_air", "description": "The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Minus one times\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. The surface called \"surface\" means the lower boundary of the atmosphere. The term \"shortwave\" means shortwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/minus_one_times_toa_outgoing_shortwave_flux.json b/data_descriptors/standard_name/minus_one_times_toa_outgoing_shortwave_flux.json index de0ce1ce1..81236266f 100644 --- a/data_descriptors/standard_name/minus_one_times_toa_outgoing_shortwave_flux.json +++ b/data_descriptors/standard_name/minus_one_times_toa_outgoing_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_one_times_toa_outgoing_shortwave_flux", + "id": "minus_one_times_toa_outgoing_shortwave_flux", "type": "standard_name", "name": "minus_one_times_toa_outgoing_shortwave_flux", "description": "\"Minus one times\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Shortwave means shortwave radiation. \"toa\" means top of atmosphere. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/minus_one_times_water_flux_into_sea_water_from_rivers.json b/data_descriptors/standard_name/minus_one_times_water_flux_into_sea_water_from_rivers.json index 582136ac3..b0d23c4e0 100644 --- a/data_descriptors/standard_name/minus_one_times_water_flux_into_sea_water_from_rivers.json +++ b/data_descriptors/standard_name/minus_one_times_water_flux_into_sea_water_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_one_times_water_flux_into_sea_water_from_rivers", + "id": "minus_one_times_water_flux_into_sea_water_from_rivers", "type": "standard_name", "name": "minus_one_times_water_flux_into_sea_water_from_rivers", "description": "The quantity minus_one_times_water_flux_into_sea_water_from_rivers is the quantity with standard name water_flux_into_sea_water_from_rivers multiplied by -1. \"Water\" means water in all phases. The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json index 9696b5374..0c9627e35 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for ammonia is NH3. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json index 219dcd250..03c88b3df 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for ammonia is NH3. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json index 487f2da9c..cc7b6e16c 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for ammonium is NH4. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json index b1fcc9e38..e33a64a8e 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for ammonium is NH4. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json index 6f04eed05..46754ce55 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json index 96eeb6606..feb0ec69e 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json index 13e3bd15d..631b296af 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json index ce70bb28a..5c60d1909 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983). The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json index 2bed1562d..7df027126 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000 K and can only be gasified by oxidation starting at temperatures above 340 degrees Celsius. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983). The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json index 43d2868f0..53ba8a60a 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The mass is the total mass of the particles. \"Insoluble aerosol\" means aerosol which is not soluble in water, such as mineral dusts. At low temperatures such particles can be efficient nuclei for ice clouds. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json index f4e67ebcf..1258481ed 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. Usually, particle bound and gaseous nitrogen compounds, such as atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), ammonia (NH3), ammonium (NH4+), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)) are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json index e7a13561b..e76552dd0 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json index af91736f0..9dd7375d7 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json index 555db1037..eb1c2645e 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json index 48234beee..0005d9a91 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json index 8f5684593..cf9aa0bf9 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json index 54ac908a1..defc415bc 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json index c26c0f589..42ae22de6 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json index b2f4bd688..8a1307583 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the sulfate anion is SO4(2-). The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json index 12044feb4..49407ed42 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The chemical formula for the sulfate anion is SO4(2-). The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json index 9b9d612bd..c70ba78d8 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for sulfur dioxide is SO2. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json index 5c47affa1..85ea452d3 100644 --- a/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", + "id": "minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", "type": "standard_name", "name": "minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for sulfur dioxide is SO2. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json index 289154898..02747ad81 100644 --- a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json +++ b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", + "id": "minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", "type": "standard_name", "name": "minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Denitrification\" is the conversion of nitrate into gaseous compounds such as nitric oxide, nitrous oxide and molecular nitrogen which are then emitted to the atmosphere. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water.", diff --git a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json index 1b3d3cad5..066a563ad 100644 --- a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json +++ b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", + "id": "minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", "type": "standard_name", "name": "minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water. \"Inorganic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json index faf06a61c..072acbe47 100644 --- a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json +++ b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", + "id": "minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", "type": "standard_name", "name": "minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water.", diff --git a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json index 44c8cdf58..f1eceb3a3 100644 --- a/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json +++ b/data_descriptors/standard_name/minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", + "id": "minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", "type": "standard_name", "name": "minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"minus_tendency\" means that the quantity described takes the opposite sign convention to that for the quantity which has the same standard name apart from this phrase, i.e. the two quantities differ from one another by a factor of -1. Thus a \"minus_tendency\" in the atmosphere means a positive deposition rate onto the underlying surface. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water. \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_carbon.json b/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_carbon.json index 500bad6ef..b25eafecf 100644 --- a/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/miscellaneous_living_matter_mass_content_of_carbon", + "id": "miscellaneous_living_matter_mass_content_of_carbon", "type": "standard_name", "name": "miscellaneous_living_matter_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. \"Miscellaneous living matter\" means all those parts of plants that are not leaf, stem, root or other separately named components. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_nitrogen.json b/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_nitrogen.json index 8c0cc999c..4226dc22a 100644 --- a/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/miscellaneous_living_matter_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/miscellaneous_living_matter_mass_content_of_nitrogen", + "id": "miscellaneous_living_matter_mass_content_of_nitrogen", "type": "standard_name", "name": "miscellaneous_living_matter_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"Miscellaneous living matter\" means all those parts of plants that are not leaf, stem, root or other separately named components. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/model_level_number.json b/data_descriptors/standard_name/model_level_number.json index 66bf58655..fdbcf0e4d 100644 --- a/data_descriptors/standard_name/model_level_number.json +++ b/data_descriptors/standard_name/model_level_number.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/model_level_number", + "id": "model_level_number", "type": "standard_name", "name": "model_level_number", "description": "Model level number should be understood as equivalent to layer number.", diff --git a/data_descriptors/standard_name/model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta.json b/data_descriptors/standard_name/model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta.json index 76deab8ed..5712c41a2 100644 --- a/data_descriptors/standard_name/model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta.json +++ b/data_descriptors/standard_name/model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta", + "id": "model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta", "type": "standard_name", "name": "model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta", "description": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by \"temperature\", \"sigma\", \"sigma_theta\", \"sigma_t\" or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_sigma_theta_difference can be used to specify the sigma_theta criterion that determines the layer thickness. Sigma-theta of sea water is the potential density (i.e. the density when moved adiabatically to a reference pressure) of water having the same temperature and salinity, minus 1000 kg m-3. The quantity model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta is sometimes referred to as the \"bowl index\".", diff --git a/data_descriptors/standard_name/model_level_number_at_convective_cloud_base.json b/data_descriptors/standard_name/model_level_number_at_convective_cloud_base.json index 86363ec19..5c9a81e30 100644 --- a/data_descriptors/standard_name/model_level_number_at_convective_cloud_base.json +++ b/data_descriptors/standard_name/model_level_number_at_convective_cloud_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/model_level_number_at_convective_cloud_base", + "id": "model_level_number_at_convective_cloud_base", "type": "standard_name", "name": "model_level_number_at_convective_cloud_base", "description": "cloud_base refers to the base of the lowest cloud. Model level number should be understood as equivalent to layer number. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/model_level_number_at_convective_cloud_top.json b/data_descriptors/standard_name/model_level_number_at_convective_cloud_top.json index f6144f0c1..3a03204b0 100644 --- a/data_descriptors/standard_name/model_level_number_at_convective_cloud_top.json +++ b/data_descriptors/standard_name/model_level_number_at_convective_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/model_level_number_at_convective_cloud_top", + "id": "model_level_number_at_convective_cloud_top", "type": "standard_name", "name": "model_level_number_at_convective_cloud_top", "description": "cloud_top refers to the top of the highest cloud. Model level number should be understood as equivalent to layer number. Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/model_level_number_at_sea_floor.json b/data_descriptors/standard_name/model_level_number_at_sea_floor.json index ea61c8266..63b3fda19 100644 --- a/data_descriptors/standard_name/model_level_number_at_sea_floor.json +++ b/data_descriptors/standard_name/model_level_number_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/model_level_number_at_sea_floor", + "id": "model_level_number_at_sea_floor", "type": "standard_name", "name": "model_level_number_at_sea_floor", "description": "The quantity with standard name model_level_number_at_sea_floor is the depth of the ocean expressed in model levels. This could be a non-integer value because some ocean models use partial cells close to the sea floor. For example, if this field were 23.4 at some location, it would mean the water column at that point comprised 23 full model levels plus 40% occupancy of the lowest (24th) gridcell.", diff --git a/data_descriptors/standard_name/model_level_number_at_top_of_atmosphere_boundary_layer.json b/data_descriptors/standard_name/model_level_number_at_top_of_atmosphere_boundary_layer.json index 4c567d556..ea9a21172 100644 --- a/data_descriptors/standard_name/model_level_number_at_top_of_atmosphere_boundary_layer.json +++ b/data_descriptors/standard_name/model_level_number_at_top_of_atmosphere_boundary_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/model_level_number_at_top_of_atmosphere_boundary_layer", + "id": "model_level_number_at_top_of_atmosphere_boundary_layer", "type": "standard_name", "name": "model_level_number_at_top_of_atmosphere_boundary_layer", "description": "Model level number should be understood as equivalent to layer number.", diff --git a/data_descriptors/standard_name/modified_fosberg_fire_weather_index.json b/data_descriptors/standard_name/modified_fosberg_fire_weather_index.json index b1b278304..f0fbd1bda 100644 --- a/data_descriptors/standard_name/modified_fosberg_fire_weather_index.json +++ b/data_descriptors/standard_name/modified_fosberg_fire_weather_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/modified_fosberg_fire_weather_index", + "id": "modified_fosberg_fire_weather_index", "type": "standard_name", "name": "modified_fosberg_fire_weather_index", "description": "The modified Fosberg Fire Weather Index (mFFWI) is a measure of the potential effect of weather conditions on wildland fire. The Fosberg Fire Weather Index is a function of temperature, wind, and humidity. It is modified with a fuel availability factor based on the Keetch Byram Drought Index.", diff --git a/data_descriptors/standard_name/modis_cloud_area_fraction.json b/data_descriptors/standard_name/modis_cloud_area_fraction.json index 67a9a79f4..e58ad76ca 100644 --- a/data_descriptors/standard_name/modis_cloud_area_fraction.json +++ b/data_descriptors/standard_name/modis_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/modis_cloud_area_fraction", + "id": "modis_cloud_area_fraction", "type": "standard_name", "name": "modis_cloud_area_fraction", "description": "The MODIS cloud area fraction is diagnosed from atmosphere model output by the MODIS simulator software in such a way as to be comparable with the observational diagnostics of MODIS (Moderate Resolution Imaging Spectroradiometer). Cloud area fraction is also called \u201ccloud amount\u201d and \u201ccloud cover.\u201d As seen from above, mean fraction of grid column occupied by cloud of optical depths and heights specified by the tau and pressure intervals given above. Dimensions of the histogram are cloud top pressure and cloud optical depth. To distinguish that these are cloud area fractions as seen by a specific satellite instrument simulator, not the same as cloud area fractions diagnosed by the native model, the prefix format of satellite name_ is employed. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion.", diff --git a/data_descriptors/standard_name/modis_ice_topped_cloud_area_fraction.json b/data_descriptors/standard_name/modis_ice_topped_cloud_area_fraction.json index 411b841eb..cae2f3e6d 100644 --- a/data_descriptors/standard_name/modis_ice_topped_cloud_area_fraction.json +++ b/data_descriptors/standard_name/modis_ice_topped_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/modis_ice_topped_cloud_area_fraction", + "id": "modis_ice_topped_cloud_area_fraction", "type": "standard_name", "name": "modis_ice_topped_cloud_area_fraction", "description": "Ice means ice-topped clouds, as seen by the MODIS simulator. To distinguish that these are cloud area fractions as seen by a specific satellite instrument simulator, not the same as cloud area fractions diagnosed by the native model, the prefix format of satellite name_ is employed. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion.", diff --git a/data_descriptors/standard_name/modis_liquid_topped_cloud_area_fraction.json b/data_descriptors/standard_name/modis_liquid_topped_cloud_area_fraction.json index 82715d30c..f302d52c5 100644 --- a/data_descriptors/standard_name/modis_liquid_topped_cloud_area_fraction.json +++ b/data_descriptors/standard_name/modis_liquid_topped_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/modis_liquid_topped_cloud_area_fraction", + "id": "modis_liquid_topped_cloud_area_fraction", "type": "standard_name", "name": "modis_liquid_topped_cloud_area_fraction", "description": "Liquid means liquid-topped clouds, as seen by the MODIS simulator. To distinguish that these are cloud area fractions as seen by a specific satellite instrument simulator, not the same as cloud area fractions diagnosed by the native model, the prefix format of satellite name_ is employed. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion.", diff --git a/data_descriptors/standard_name/moisture_content_of_soil_layer_at_field_capacity.json b/data_descriptors/standard_name/moisture_content_of_soil_layer_at_field_capacity.json index 5d307c866..02320a238 100644 --- a/data_descriptors/standard_name/moisture_content_of_soil_layer_at_field_capacity.json +++ b/data_descriptors/standard_name/moisture_content_of_soil_layer_at_field_capacity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moisture_content_of_soil_layer_at_field_capacity", + "id": "moisture_content_of_soil_layer_at_field_capacity", "type": "standard_name", "name": "moisture_content_of_soil_layer_at_field_capacity", "description": "\"moisture\" means water in all phases contained in soil. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s). The field capacity of soil is the maximum content of water it can retain against gravitational drainage.", diff --git a/data_descriptors/standard_name/mole_concentration_of_acetic_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_acetic_acid_in_air.json index c135386e3..b3e9f82e9 100644 --- a/data_descriptors/standard_name/mole_concentration_of_acetic_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_acetic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_acetic_acid_in_air", + "id": "mole_concentration_of_acetic_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_acetic_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/mole_concentration_of_aceto_nitrile_in_air.json b/data_descriptors/standard_name/mole_concentration_of_aceto_nitrile_in_air.json index 74667885e..a951f8097 100644 --- a/data_descriptors/standard_name/mole_concentration_of_aceto_nitrile_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_aceto_nitrile_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_aceto_nitrile_in_air", + "id": "mole_concentration_of_aceto_nitrile_in_air", "type": "standard_name", "name": "mole_concentration_of_aceto_nitrile_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/mole_concentration_of_adenosine_triphosphate_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_adenosine_triphosphate_in_sea_water.json index 35db954e6..7af30d0a6 100644 --- a/data_descriptors/standard_name/mole_concentration_of_adenosine_triphosphate_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_adenosine_triphosphate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_adenosine_triphosphate_in_sea_water", + "id": "mole_concentration_of_adenosine_triphosphate_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_adenosine_triphosphate_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/ATPXZZDZ/2/.", diff --git a/data_descriptors/standard_name/mole_concentration_of_alpha_hexachlorocyclohexane_in_air.json b/data_descriptors/standard_name/mole_concentration_of_alpha_hexachlorocyclohexane_in_air.json index 36ad994d3..618f6ccda 100644 --- a/data_descriptors/standard_name/mole_concentration_of_alpha_hexachlorocyclohexane_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_alpha_hexachlorocyclohexane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_alpha_hexachlorocyclohexane_in_air", + "id": "mole_concentration_of_alpha_hexachlorocyclohexane_in_air", "type": "standard_name", "name": "mole_concentration_of_alpha_hexachlorocyclohexane_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for alpha_hexachlorocyclohexane is C6H6Cl6.", diff --git a/data_descriptors/standard_name/mole_concentration_of_alpha_pinene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_alpha_pinene_in_air.json index 478234c0e..0fde0c3c6 100644 --- a/data_descriptors/standard_name/mole_concentration_of_alpha_pinene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_alpha_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_alpha_pinene_in_air", + "id": "mole_concentration_of_alpha_pinene_in_air", "type": "standard_name", "name": "mole_concentration_of_alpha_pinene_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ammonia_in_air.json b/data_descriptors/standard_name/mole_concentration_of_ammonia_in_air.json index cd02202b6..f8d2b8dfa 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ammonia_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_ammonia_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ammonia_in_air", + "id": "mole_concentration_of_ammonia_in_air", "type": "standard_name", "name": "mole_concentration_of_ammonia_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ammonium_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_ammonium_in_sea_water.json index d10ad6140..8bcdd4d2b 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ammonium_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_ammonium_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ammonium_in_sea_water", + "id": "mole_concentration_of_ammonium_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_ammonium_in_sea_water", "description": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json index d1a76ee8f..59eae4ea7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mole_concentration_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituentsof A. The abbreviation \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water.json index b8febd266..e0f90f30d 100644 --- a/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation.json b/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation.json index eff4896f9..b93f5dc4e 100644 --- a/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation.json +++ b/data_descriptors/standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation", + "id": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation", "type": "standard_name", "name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Mole concentration at saturation\" means the mole concentration in a saturated solution. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_atomic_bromine_in_air.json b/data_descriptors/standard_name/mole_concentration_of_atomic_bromine_in_air.json index 314b0d47c..5f3ff9a54 100644 --- a/data_descriptors/standard_name/mole_concentration_of_atomic_bromine_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_atomic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_atomic_bromine_in_air", + "id": "mole_concentration_of_atomic_bromine_in_air", "type": "standard_name", "name": "mole_concentration_of_atomic_bromine_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic bromine is Br.", diff --git a/data_descriptors/standard_name/mole_concentration_of_atomic_chlorine_in_air.json b/data_descriptors/standard_name/mole_concentration_of_atomic_chlorine_in_air.json index bc467c707..638889b43 100644 --- a/data_descriptors/standard_name/mole_concentration_of_atomic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_atomic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_atomic_chlorine_in_air", + "id": "mole_concentration_of_atomic_chlorine_in_air", "type": "standard_name", "name": "mole_concentration_of_atomic_chlorine_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/mole_concentration_of_atomic_nitrogen_in_air.json b/data_descriptors/standard_name/mole_concentration_of_atomic_nitrogen_in_air.json index 68cd1c94d..2c081ba70 100644 --- a/data_descriptors/standard_name/mole_concentration_of_atomic_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_atomic_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_atomic_nitrogen_in_air", + "id": "mole_concentration_of_atomic_nitrogen_in_air", "type": "standard_name", "name": "mole_concentration_of_atomic_nitrogen_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water.json index 525e681c0..a54422111 100644 --- a/data_descriptors/standard_name/mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_benzene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_benzene_in_air.json index a02012379..96a94d277 100644 --- a/data_descriptors/standard_name/mole_concentration_of_benzene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_benzene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_benzene_in_air", + "id": "mole_concentration_of_benzene_in_air", "type": "standard_name", "name": "mole_concentration_of_benzene_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_beta_pinene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_beta_pinene_in_air.json index 646e6d20b..f09371d2f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_beta_pinene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_beta_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_beta_pinene_in_air", + "id": "mole_concentration_of_beta_pinene_in_air", "type": "standard_name", "name": "mole_concentration_of_beta_pinene_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json index 4101ec888..e73f8d8fc 100644 --- a/data_descriptors/standard_name/mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mole_concentration_of_biogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json index b4727d694..43ee65ad5 100644 --- a/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_biological_taxon_expressed_as_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json index 5f01d2489..975577f18 100644 --- a/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_biological_taxon_expressed_as_nitrogen_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/mole_concentration_of_bromine_chloride_in_air.json b/data_descriptors/standard_name/mole_concentration_of_bromine_chloride_in_air.json index 4a6eec6ce..f8501e0d2 100644 --- a/data_descriptors/standard_name/mole_concentration_of_bromine_chloride_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_bromine_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_bromine_chloride_in_air", + "id": "mole_concentration_of_bromine_chloride_in_air", "type": "standard_name", "name": "mole_concentration_of_bromine_chloride_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/mole_concentration_of_bromine_monoxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_bromine_monoxide_in_air.json index e5b3db4a5..4490e933b 100644 --- a/data_descriptors/standard_name/mole_concentration_of_bromine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_bromine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_bromine_monoxide_in_air", + "id": "mole_concentration_of_bromine_monoxide_in_air", "type": "standard_name", "name": "mole_concentration_of_bromine_monoxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/mole_concentration_of_bromine_nitrate_in_air.json b/data_descriptors/standard_name/mole_concentration_of_bromine_nitrate_in_air.json index 5e1c3082d..9f6d68cae 100644 --- a/data_descriptors/standard_name/mole_concentration_of_bromine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_bromine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_bromine_nitrate_in_air", + "id": "mole_concentration_of_bromine_nitrate_in_air", "type": "standard_name", "name": "mole_concentration_of_bromine_nitrate_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for bromine nitrate is BrONO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_brox_expressed_as_bromine_in_air.json b/data_descriptors/standard_name/mole_concentration_of_brox_expressed_as_bromine_in_air.json index ee7bd05af..8f99f14e7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_brox_expressed_as_bromine_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_brox_expressed_as_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_brox_expressed_as_bromine_in_air", + "id": "mole_concentration_of_brox_expressed_as_bromine_in_air", "type": "standard_name", "name": "mole_concentration_of_brox_expressed_as_bromine_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_butane_in_air.json b/data_descriptors/standard_name/mole_concentration_of_butane_in_air.json index 6a5ace169..466e7bacd 100644 --- a/data_descriptors/standard_name/mole_concentration_of_butane_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_butane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_butane_in_air", + "id": "mole_concentration_of_butane_in_air", "type": "standard_name", "name": "mole_concentration_of_butane_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water.json index 6decacd03..02023d7e7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Calcareous phytoplankton\" are phytoplankton that produce calcite. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water.json index 955f502e8..45990ebba 100644 --- a/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation.json b/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation.json index 099eeab2d..567229bb4 100644 --- a/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation.json +++ b/data_descriptors/standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation", + "id": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation", "type": "standard_name", "name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Mole concentration at saturation\" means the mole concentration in a saturated solution.The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbon_dioxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_carbon_dioxide_in_air.json index cb25c8bfd..f7f2be226 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbon_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbon_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbon_dioxide_in_air", + "id": "mole_concentration_of_carbon_dioxide_in_air", "type": "standard_name", "name": "mole_concentration_of_carbon_dioxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbon_monoxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_carbon_monoxide_in_air.json index 04e541005..55767f7e1 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbon_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbon_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbon_monoxide_in_air", + "id": "mole_concentration_of_carbon_monoxide_in_air", "type": "standard_name", "name": "mole_concentration_of_carbon_monoxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbon_tetrachloride_in_air.json b/data_descriptors/standard_name/mole_concentration_of_carbon_tetrachloride_in_air.json index fea67668e..72fa18373 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbon_tetrachloride_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbon_tetrachloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbon_tetrachloride_in_air", + "id": "mole_concentration_of_carbon_tetrachloride_in_air", "type": "standard_name", "name": "mole_concentration_of_carbon_tetrachloride_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water.json index c7c501833..b196e3bb7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula of the carbonate anion is CO3 with an electrical charge of minus two.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water.json index 72a0a73cd..9f0be73a5 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", + "id": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula of the carbonate anion is CO3 with an electrical charge of minus two. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. At a given salinity, the thermodynamic equilibrium is that between dissolved carbonate ion and solid aragonite. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water.json index b3849c130..f1ff0153a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", + "id": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula of the carbonate anion is CO3 with an electrical charge of minus two. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. At a given salinity, the thermodynamic equilibrium is that between dissolved carbonate ion and solid calcite. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water.json index 957aaba5f..cc513e914 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula of the carbonate anion is CO3 with a charge of minus two.", diff --git a/data_descriptors/standard_name/mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water.json index 8cadf31a7..cf3aa904f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula of the carbonate anion is CO3 with an electrical charge of minus two.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc113_in_air.json b/data_descriptors/standard_name/mole_concentration_of_cfc113_in_air.json index c5dd6078a..c6dc27c3c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc113_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc113_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc113_in_air", + "id": "mole_concentration_of_cfc113_in_air", "type": "standard_name", "name": "mole_concentration_of_cfc113_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc113a_in_air.json b/data_descriptors/standard_name/mole_concentration_of_cfc113a_in_air.json index 1abf25d41..71073e6a0 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc113a_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc113a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc113a_in_air", + "id": "mole_concentration_of_cfc113a_in_air", "type": "standard_name", "name": "mole_concentration_of_cfc113a_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc114_in_air.json b/data_descriptors/standard_name/mole_concentration_of_cfc114_in_air.json index e6f282fed..f70eae586 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc114_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc114_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc114_in_air", + "id": "mole_concentration_of_cfc114_in_air", "type": "standard_name", "name": "mole_concentration_of_cfc114_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc115_in_air.json b/data_descriptors/standard_name/mole_concentration_of_cfc115_in_air.json index f7963f41f..033e9286b 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc115_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc115_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc115_in_air", + "id": "mole_concentration_of_cfc115_in_air", "type": "standard_name", "name": "mole_concentration_of_cfc115_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc11_in_air.json b/data_descriptors/standard_name/mole_concentration_of_cfc11_in_air.json index ddf5d9f52..bc53719fb 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc11_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc11_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc11_in_air", + "id": "mole_concentration_of_cfc11_in_air", "type": "standard_name", "name": "mole_concentration_of_cfc11_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc11_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_cfc11_in_sea_water.json index 582f934bd..bfd1b26a2 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc11_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc11_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc11_in_sea_water", + "id": "mole_concentration_of_cfc11_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_cfc11_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc12_in_air.json b/data_descriptors/standard_name/mole_concentration_of_cfc12_in_air.json index 596c73728..88b82457c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc12_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc12_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc12_in_air", + "id": "mole_concentration_of_cfc12_in_air", "type": "standard_name", "name": "mole_concentration_of_cfc12_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_cfc12_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_cfc12_in_sea_water.json index 481b854ff..6bc153000 100644 --- a/data_descriptors/standard_name/mole_concentration_of_cfc12_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_cfc12_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_cfc12_in_sea_water", + "id": "mole_concentration_of_cfc12_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_cfc12_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_chlorine_dioxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_chlorine_dioxide_in_air.json index a51edf1d1..80af83c45 100644 --- a/data_descriptors/standard_name/mole_concentration_of_chlorine_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_chlorine_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_chlorine_dioxide_in_air", + "id": "mole_concentration_of_chlorine_dioxide_in_air", "type": "standard_name", "name": "mole_concentration_of_chlorine_dioxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/mole_concentration_of_chlorine_monoxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_chlorine_monoxide_in_air.json index 19ad79fb7..0bc07f038 100644 --- a/data_descriptors/standard_name/mole_concentration_of_chlorine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_chlorine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_chlorine_monoxide_in_air", + "id": "mole_concentration_of_chlorine_monoxide_in_air", "type": "standard_name", "name": "mole_concentration_of_chlorine_monoxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/mole_concentration_of_chlorine_nitrate_in_air.json b/data_descriptors/standard_name/mole_concentration_of_chlorine_nitrate_in_air.json index ec3901c59..8a1efbc81 100644 --- a/data_descriptors/standard_name/mole_concentration_of_chlorine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_chlorine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_chlorine_nitrate_in_air", + "id": "mole_concentration_of_chlorine_nitrate_in_air", "type": "standard_name", "name": "mole_concentration_of_chlorine_nitrate_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_clox_expressed_as_chlorine_in_air.json b/data_descriptors/standard_name/mole_concentration_of_clox_expressed_as_chlorine_in_air.json index fba2e9059..7e69c1171 100644 --- a/data_descriptors/standard_name/mole_concentration_of_clox_expressed_as_chlorine_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_clox_expressed_as_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_clox_expressed_as_chlorine_in_air", + "id": "mole_concentration_of_clox_expressed_as_chlorine_in_air", "type": "standard_name", "name": "mole_concentration_of_clox_expressed_as_chlorine_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as \"Cly\", describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json index 5c16f3dd8..3f74a761a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Diatoms are single-celled phytoplankton with an external skeleton made of silica.Phytoplankton are autotrophic prokaryotic or eukaryotic algae that live near the water surface where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json index 40cff30f8..b6abfc03c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_diatoms_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated in terms of B alone, neglecting all other chemical constituents of A. Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json index 554bc2e18..4006879f1 100644 --- a/data_descriptors/standard_name/mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_diazotrophic_phytoplankton_expressed_as_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dichlorine_peroxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_dichlorine_peroxide_in_air.json index b920c1679..7ba913f29 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dichlorine_peroxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_dichlorine_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dichlorine_peroxide_in_air", + "id": "mole_concentration_of_dichlorine_peroxide_in_air", "type": "standard_name", "name": "mole_concentration_of_dichlorine_peroxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_air.json index d7e15f865..32fe75c68 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dimethyl_sulfide_in_air", + "id": "mole_concentration_of_dimethyl_sulfide_in_air", "type": "standard_name", "name": "mole_concentration_of_dimethyl_sulfide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_sea_water.json index 5f9e5705d..0ae253a90 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dimethyl_sulfide_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dimethyl_sulfide_in_sea_water", + "id": "mole_concentration_of_dimethyl_sulfide_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dimethyl_sulfide_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dinitrogen_pentoxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_dinitrogen_pentoxide_in_air.json index dd432a8b0..33865685d 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dinitrogen_pentoxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_dinitrogen_pentoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dinitrogen_pentoxide_in_air", + "id": "mole_concentration_of_dinitrogen_pentoxide_in_air", "type": "standard_name", "name": "mole_concentration_of_dinitrogen_pentoxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_13C_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_13C_in_sea_water.json index 7f927fb72..41bcb614a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_13C_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_13C_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_13C_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_14C_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_14C_in_sea_water.json index 890308272..061286089 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_14C_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_14C_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_14C_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water.json index 05019d21d..64e9e12b7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water.json index cc8636deb..a3e76889f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water", + "id": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_floor_sediment_pore_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Sea floor sediment\" is sediment deposited at the sea bed. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_water.json index 62e7e9267..23cffb9a3 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water.json index 1b7677f4a..91f3ba176 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water.json index 9f901d9a6..135a9def8 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic nitrogen\" describes a family of chemical species which, in an ocean model, usually includes nitrite, nitrate and ammonium which act as nitrogen nutrients. \"Inorganic nitrogen\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water.json index 910fcffdc..a8d08a536 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic phosphorus\" means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_silicon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_silicon_in_sea_water.json index cf7f14dca..3ea5278a6 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_silicon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_inorganic_silicon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", + "id": "mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic silicon\" means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_iron_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_iron_in_sea_water.json index 2c35b57a4..5fc870b5c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_iron_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_iron_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_iron_in_sea_water", + "id": "mole_concentration_of_dissolved_iron_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_iron_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water.json index 0423940ba..5af8ed067 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water", + "id": "mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_molecular_nitrogen_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for molecular nitrogen is N2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json index 964d38395..00a4e6594 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", + "id": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for molecular oxygen is O2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation.json index f056fab4e..31c2896eb 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", + "id": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", "type": "standard_name", "name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", "description": "\"Mole concentration at saturation\" means the mole concentration in a saturated solution. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile.json index 5f9d83457..5c409eedb 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile", + "id": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile", "type": "standard_name", "name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The concentration of any chemical species, whether particulate or dissolved, may vary with depth in the ocean. A depth profile may go through one or more local minima in concentration. The mole_concentration_of_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile is the mole concentration of oxygen at the local minimum in the concentration profile that occurs closest to the sea surface. The chemical formula for molecular oxygen is O2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_nitrogen_in_sea_water.json index af9836f53..04682f4e3 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_nitrogen_in_sea_water", + "id": "mole_concentration_of_dissolved_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_nitrogen_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved nitrogen\" means the sum of all nitrogen in solution: inorganic nitrogen (nitrite, nitrate and ammonium) plus nitrogen in carbon compounds.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_13C_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_13C_in_sea_water.json index 2c7f9b871..060e62baa 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_13C_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_13C_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_organic_13C_in_sea_water", + "id": "mole_concentration_of_dissolved_organic_13C_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_organic_13C_in_sea_water", "description": "The sum of dissolved organic carbon-13 component concentrations. \"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water.json index dc6b87b1a..d26ee7548 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water", + "id": "mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_organic_carbon_in_sea_floor_sediment_pore_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen' or a phrase such as \"nox_expressed_as_nitrogen\". \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Sea floor sediment\" is sediment deposited at the sea bed. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_water.json index 8e326a734..15d0bea6a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_organic_carbon_in_sea_water", + "id": "mole_concentration_of_dissolved_organic_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_organic_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen' or a phrase such as \"nox_expressed_as_nitrogen\". \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_nitrogen_in_sea_water.json index 3d1003496..f0fd2fa59 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_organic_nitrogen_in_sea_water", + "id": "mole_concentration_of_dissolved_organic_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_organic_nitrogen_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved organic nitrogen\" describes the nitrogen held in carbon compounds in solution. These are mostly generated by plankton excretion and decay.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_phosphorus_in_sea_water.json index d894c8324..a24b9a4e1 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_organic_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_organic_phosphorus_in_sea_water", + "id": "mole_concentration_of_dissolved_organic_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_organic_phosphorus_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Organic phosphorus\" means phosphorus in carbon compounds. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/ORGPDSZZ/4/.", diff --git a/data_descriptors/standard_name/mole_concentration_of_dissolved_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_dissolved_phosphorus_in_sea_water.json index d83ed02b7..2671a81cc 100644 --- a/data_descriptors/standard_name/mole_concentration_of_dissolved_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_dissolved_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_dissolved_phosphorus_in_sea_water", + "id": "mole_concentration_of_dissolved_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_dissolved_phosphorus_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Phosphorus means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/TPHSDSZZ/6/.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ethane_in_air.json b/data_descriptors/standard_name/mole_concentration_of_ethane_in_air.json index b692201e0..cd07a0d15 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ethane_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_ethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ethane_in_air", + "id": "mole_concentration_of_ethane_in_air", "type": "standard_name", "name": "mole_concentration_of_ethane_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes.There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ethanol_in_air.json b/data_descriptors/standard_name/mole_concentration_of_ethanol_in_air.json index 2eade9e33..97fa2405a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ethanol_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_ethanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ethanol_in_air", + "id": "mole_concentration_of_ethanol_in_air", "type": "standard_name", "name": "mole_concentration_of_ethanol_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ethene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_ethene_in_air.json index 4a7ff69b4..da09010d5 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ethene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_ethene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ethene_in_air", + "id": "mole_concentration_of_ethene_in_air", "type": "standard_name", "name": "mole_concentration_of_ethene_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes.There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ethyne_in_air.json b/data_descriptors/standard_name/mole_concentration_of_ethyne_in_air.json index 3cfb3a1df..3c915316c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ethyne_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_ethyne_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ethyne_in_air", + "id": "mole_concentration_of_ethyne_in_air", "type": "standard_name", "name": "mole_concentration_of_ethyne_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/mole_concentration_of_formaldehyde_in_air.json b/data_descriptors/standard_name/mole_concentration_of_formaldehyde_in_air.json index e0af9b241..05ae20ad3 100644 --- a/data_descriptors/standard_name/mole_concentration_of_formaldehyde_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_formaldehyde_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_formaldehyde_in_air", + "id": "mole_concentration_of_formaldehyde_in_air", "type": "standard_name", "name": "mole_concentration_of_formaldehyde_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/mole_concentration_of_formic_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_formic_acid_in_air.json index 6149564a9..fbd216433 100644 --- a/data_descriptors/standard_name/mole_concentration_of_formic_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_formic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_formic_acid_in_air", + "id": "mole_concentration_of_formic_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_formic_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/mole_concentration_of_gaseous_divalent_mercury_in_air.json b/data_descriptors/standard_name/mole_concentration_of_gaseous_divalent_mercury_in_air.json index 94ed79c7a..2bed17d00 100644 --- a/data_descriptors/standard_name/mole_concentration_of_gaseous_divalent_mercury_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_gaseous_divalent_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_gaseous_divalent_mercury_in_air", + "id": "mole_concentration_of_gaseous_divalent_mercury_in_air", "type": "standard_name", "name": "mole_concentration_of_gaseous_divalent_mercury_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s)in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/mole_concentration_of_gaseous_elemental_mercury_in_air.json b/data_descriptors/standard_name/mole_concentration_of_gaseous_elemental_mercury_in_air.json index 8376aad29..2349c8b42 100644 --- a/data_descriptors/standard_name/mole_concentration_of_gaseous_elemental_mercury_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_gaseous_elemental_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_gaseous_elemental_mercury_in_air", + "id": "mole_concentration_of_gaseous_elemental_mercury_in_air", "type": "standard_name", "name": "mole_concentration_of_gaseous_elemental_mercury_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for mercury is Hg.", diff --git a/data_descriptors/standard_name/mole_concentration_of_guanosine_triphosphate_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_guanosine_triphosphate_in_sea_water.json index e8ea76cbf..9a0d31352 100644 --- a/data_descriptors/standard_name/mole_concentration_of_guanosine_triphosphate_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_guanosine_triphosphate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_guanosine_triphosphate_in_sea_water", + "id": "mole_concentration_of_guanosine_triphosphate_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_guanosine_triphosphate_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of guanosine triphosphate is C10H16N5O14P3.", diff --git a/data_descriptors/standard_name/mole_concentration_of_halon1202_in_air.json b/data_descriptors/standard_name/mole_concentration_of_halon1202_in_air.json index c7ac12974..89f33a502 100644 --- a/data_descriptors/standard_name/mole_concentration_of_halon1202_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_halon1202_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_halon1202_in_air", + "id": "mole_concentration_of_halon1202_in_air", "type": "standard_name", "name": "mole_concentration_of_halon1202_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_halon1211_in_air.json b/data_descriptors/standard_name/mole_concentration_of_halon1211_in_air.json index 82d29b1b2..88942a4d7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_halon1211_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_halon1211_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_halon1211_in_air", + "id": "mole_concentration_of_halon1211_in_air", "type": "standard_name", "name": "mole_concentration_of_halon1211_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_halon1301_in_air.json b/data_descriptors/standard_name/mole_concentration_of_halon1301_in_air.json index 0bf23dfb6..098872a8f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_halon1301_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_halon1301_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_halon1301_in_air", + "id": "mole_concentration_of_halon1301_in_air", "type": "standard_name", "name": "mole_concentration_of_halon1301_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_halon2402_in_air.json b/data_descriptors/standard_name/mole_concentration_of_halon2402_in_air.json index cd238d2d5..ccaec7447 100644 --- a/data_descriptors/standard_name/mole_concentration_of_halon2402_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_halon2402_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_halon2402_in_air", + "id": "mole_concentration_of_halon2402_in_air", "type": "standard_name", "name": "mole_concentration_of_halon2402_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hcc140a_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hcc140a_in_air.json index 0626cb19e..4b641e792 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hcc140a_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hcc140a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hcc140a_in_air", + "id": "mole_concentration_of_hcc140a_in_air", "type": "standard_name", "name": "mole_concentration_of_hcc140a_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hcfc141b_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hcfc141b_in_air.json index 28add8e93..faf6d5168 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hcfc141b_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hcfc141b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hcfc141b_in_air", + "id": "mole_concentration_of_hcfc141b_in_air", "type": "standard_name", "name": "mole_concentration_of_hcfc141b_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hcfc142b_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hcfc142b_in_air.json index d05aceeb9..8662693f8 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hcfc142b_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hcfc142b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hcfc142b_in_air", + "id": "mole_concentration_of_hcfc142b_in_air", "type": "standard_name", "name": "mole_concentration_of_hcfc142b_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hcfc22_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hcfc22_in_air.json index fd0cb33e4..073f81ef6 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hcfc22_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hcfc22_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hcfc22_in_air", + "id": "mole_concentration_of_hcfc22_in_air", "type": "standard_name", "name": "mole_concentration_of_hcfc22_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hexachlorobiphenyl_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hexachlorobiphenyl_in_air.json index a6a0e0049..1f480a113 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hexachlorobiphenyl_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hexachlorobiphenyl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hexachlorobiphenyl_in_air", + "id": "mole_concentration_of_hexachlorobiphenyl_in_air", "type": "standard_name", "name": "mole_concentration_of_hexachlorobiphenyl_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hexachlorobiphenyl is C12H4Cl6. This structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hox_expressed_as_hydrogen_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hox_expressed_as_hydrogen_in_air.json index b63b04d8d..3b5e7e9b0 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hox_expressed_as_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hox_expressed_as_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hox_expressed_as_hydrogen_in_air", + "id": "mole_concentration_of_hox_expressed_as_hydrogen_in_air", "type": "standard_name", "name": "mole_concentration_of_hox_expressed_as_hydrogen_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. \"HOx\" means a combination of two radical species containing hydrogen and oxygen: OH and HO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydrogen_bromide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hydrogen_bromide_in_air.json index 6cc32e194..a4688b68d 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydrogen_bromide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydrogen_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydrogen_bromide_in_air", + "id": "mole_concentration_of_hydrogen_bromide_in_air", "type": "standard_name", "name": "mole_concentration_of_hydrogen_bromide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydrogen_chloride_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hydrogen_chloride_in_air.json index dab1d3ad9..40d00c4ba 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydrogen_chloride_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydrogen_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydrogen_chloride_in_air", + "id": "mole_concentration_of_hydrogen_chloride_in_air", "type": "standard_name", "name": "mole_concentration_of_hydrogen_chloride_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydrogen_cyanide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hydrogen_cyanide_in_air.json index c4380c7ef..9b1d0ba46 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydrogen_cyanide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydrogen_cyanide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydrogen_cyanide_in_air", + "id": "mole_concentration_of_hydrogen_cyanide_in_air", "type": "standard_name", "name": "mole_concentration_of_hydrogen_cyanide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydrogen_peroxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hydrogen_peroxide_in_air.json index cbf89297f..f364c469c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydrogen_peroxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydrogen_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydrogen_peroxide_in_air", + "id": "mole_concentration_of_hydrogen_peroxide_in_air", "type": "standard_name", "name": "mole_concentration_of_hydrogen_peroxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydrogen_sulfide_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_hydrogen_sulfide_in_sea_water.json index c3b81d6d6..e5cab3cd9 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydrogen_sulfide_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydrogen_sulfide_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydrogen_sulfide_in_sea_water", + "id": "mole_concentration_of_hydrogen_sulfide_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_hydrogen_sulfide_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of hydrogen sulfide is H2S.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydroperoxyl_radical_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hydroperoxyl_radical_in_air.json index 568e5b4fb..fcdce6613 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydroperoxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydroperoxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydroperoxyl_radical_in_air", + "id": "mole_concentration_of_hydroperoxyl_radical_in_air", "type": "standard_name", "name": "mole_concentration_of_hydroperoxyl_radical_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for the hydroperoxyl radical is HO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hydroxyl_radical_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hydroxyl_radical_in_air.json index b1b208254..6221f75a9 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hydroxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hydroxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hydroxyl_radical_in_air", + "id": "mole_concentration_of_hydroxyl_radical_in_air", "type": "standard_name", "name": "mole_concentration_of_hydroxyl_radical_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hypobromous_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hypobromous_acid_in_air.json index f1a8d828c..5c4076340 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hypobromous_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hypobromous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hypobromous_acid_in_air", + "id": "mole_concentration_of_hypobromous_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_hypobromous_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/mole_concentration_of_hypochlorous_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_hypochlorous_acid_in_air.json index 4ad1849c6..2fab3eb77 100644 --- a/data_descriptors/standard_name/mole_concentration_of_hypochlorous_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_hypochlorous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_hypochlorous_acid_in_air", + "id": "mole_concentration_of_hypochlorous_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_hypochlorous_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/mole_concentration_of_inorganic_bromine_in_air.json b/data_descriptors/standard_name/mole_concentration_of_inorganic_bromine_in_air.json index 7262d2492..7e6b9823c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_inorganic_bromine_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_inorganic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_inorganic_bromine_in_air", + "id": "mole_concentration_of_inorganic_bromine_in_air", "type": "standard_name", "name": "mole_concentration_of_inorganic_bromine_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_inorganic_chlorine_in_air.json b/data_descriptors/standard_name/mole_concentration_of_inorganic_chlorine_in_air.json index e12497bfc..c4262c479 100644 --- a/data_descriptors/standard_name/mole_concentration_of_inorganic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_inorganic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_inorganic_chlorine_in_air", + "id": "mole_concentration_of_inorganic_chlorine_in_air", "type": "standard_name", "name": "mole_concentration_of_inorganic_chlorine_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. \"Inorganic chlorine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"clox\" are used for quantities that contain all inorganic chlorine species except HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_isoprene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_isoprene_in_air.json index e1ab42aee..72b1fa9c1 100644 --- a/data_descriptors/standard_name/mole_concentration_of_isoprene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_isoprene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_isoprene_in_air", + "id": "mole_concentration_of_isoprene_in_air", "type": "standard_name", "name": "mole_concentration_of_isoprene_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_limonene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_limonene_in_air.json index 8e8ac12ec..33d31cbff 100644 --- a/data_descriptors/standard_name/mole_concentration_of_limonene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_limonene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_limonene_in_air", + "id": "mole_concentration_of_limonene_in_air", "type": "standard_name", "name": "mole_concentration_of_limonene_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water.json index c7d2154fa..dde561abf 100644 --- a/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration' means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where Xis a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Mesozooplankton are zooplankton ranging between 20 micrometers and 200 micrometers in size.", diff --git a/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water.json index dad73a26f..af886d4e8 100644 --- a/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_mesozooplankton_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated in terms of B alone, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_methane_in_air.json b/data_descriptors/standard_name/mole_concentration_of_methane_in_air.json index 6d0ada2a0..c55acc4fe 100644 --- a/data_descriptors/standard_name/mole_concentration_of_methane_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_methane_in_air", + "id": "mole_concentration_of_methane_in_air", "type": "standard_name", "name": "mole_concentration_of_methane_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_methanol_in_air.json b/data_descriptors/standard_name/mole_concentration_of_methanol_in_air.json index e0afa1137..60182c3ce 100644 --- a/data_descriptors/standard_name/mole_concentration_of_methanol_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_methanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_methanol_in_air", + "id": "mole_concentration_of_methanol_in_air", "type": "standard_name", "name": "mole_concentration_of_methanol_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/mole_concentration_of_methyl_bromide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_methyl_bromide_in_air.json index ba18e8b32..65f3a79d4 100644 --- a/data_descriptors/standard_name/mole_concentration_of_methyl_bromide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_methyl_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_methyl_bromide_in_air", + "id": "mole_concentration_of_methyl_bromide_in_air", "type": "standard_name", "name": "mole_concentration_of_methyl_bromide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_methyl_chloride_in_air.json b/data_descriptors/standard_name/mole_concentration_of_methyl_chloride_in_air.json index a9eb15160..fa65b9ce4 100644 --- a/data_descriptors/standard_name/mole_concentration_of_methyl_chloride_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_methyl_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_methyl_chloride_in_air", + "id": "mole_concentration_of_methyl_chloride_in_air", "type": "standard_name", "name": "mole_concentration_of_methyl_chloride_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/mole_concentration_of_methyl_hydroperoxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_methyl_hydroperoxide_in_air.json index 4fb4000a1..574b1c610 100644 --- a/data_descriptors/standard_name/mole_concentration_of_methyl_hydroperoxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_methyl_hydroperoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_methyl_hydroperoxide_in_air", + "id": "mole_concentration_of_methyl_hydroperoxide_in_air", "type": "standard_name", "name": "mole_concentration_of_methyl_hydroperoxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/mole_concentration_of_methyl_peroxy_radical_in_air.json b/data_descriptors/standard_name/mole_concentration_of_methyl_peroxy_radical_in_air.json index ec86f1551..3bb919191 100644 --- a/data_descriptors/standard_name/mole_concentration_of_methyl_peroxy_radical_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_methyl_peroxy_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_methyl_peroxy_radical_in_air", + "id": "mole_concentration_of_methyl_peroxy_radical_in_air", "type": "standard_name", "name": "mole_concentration_of_methyl_peroxy_radical_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl_peroxy_radical is CH3O2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water.json index a6e86c7fd..68cdb3bbc 100644 --- a/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration' means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where Xis a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Microzooplankton are zooplankton of less than 20 micrometers in size.", diff --git a/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water.json index 49457fdbf..00c4e4b33 100644 --- a/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_microzooplankton_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated in terms of B alone, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water.json index 3da9ce242..f0988e300 100644 --- a/data_descriptors/standard_name/mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water.json index 35307a2aa..df20544d2 100644 --- a/data_descriptors/standard_name/mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Miscellaneous zooplankton\" are all those zooplankton that are not mesozooplankton, microzooplankton or other separately named components of the zooplankton population.", diff --git a/data_descriptors/standard_name/mole_concentration_of_molecular_hydrogen_in_air.json b/data_descriptors/standard_name/mole_concentration_of_molecular_hydrogen_in_air.json index 225f061ad..7fc4bde65 100644 --- a/data_descriptors/standard_name/mole_concentration_of_molecular_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_molecular_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_molecular_hydrogen_in_air", + "id": "mole_concentration_of_molecular_hydrogen_in_air", "type": "standard_name", "name": "mole_concentration_of_molecular_hydrogen_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrate_and_nitrite_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_nitrate_and_nitrite_in_sea_water.json index 5be87df65..89d72e264 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrate_and_nitrite_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrate_and_nitrite_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrate_and_nitrite_in_sea_water", + "id": "mole_concentration_of_nitrate_and_nitrite_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_nitrate_and_nitrite_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for the nitrate anion is NO3-. The chemical formula for the nitrite anion is NO2-.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrate_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_nitrate_in_sea_water.json index 8401bee2d..7c4ebc4c7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrate_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrate_in_sea_water", + "id": "mole_concentration_of_nitrate_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_nitrate_in_sea_water", "description": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrate_radical_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitrate_radical_in_air.json index 5561da1a0..3d03dccdf 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrate_radical_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrate_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrate_radical_in_air", + "id": "mole_concentration_of_nitrate_radical_in_air", "type": "standard_name", "name": "mole_concentration_of_nitrate_radical_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitric_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitric_acid_in_air.json index 4d069915a..09056d46f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitric_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitric_acid_in_air", + "id": "mole_concentration_of_nitric_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_nitric_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json index aa5433a95..70ccd1b5c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", + "id": "mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mole_concentration_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The chemical formula for nitric acid is HNO3. Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrite_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_nitrite_in_sea_water.json index e8ee4f6d8..d694a239a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrite_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrite_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrite_in_sea_water", + "id": "mole_concentration_of_nitrite_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_nitrite_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for the nitrite anion is NO2-.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrogen_dioxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitrogen_dioxide_in_air.json index 25bbb488f..7d352f5fa 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrogen_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrogen_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrogen_dioxide_in_air", + "id": "mole_concentration_of_nitrogen_dioxide_in_air", "type": "standard_name", "name": "mole_concentration_of_nitrogen_dioxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrogen_monoxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitrogen_monoxide_in_air.json index b8324e046..7f9e396b3 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrogen_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrogen_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrogen_monoxide_in_air", + "id": "mole_concentration_of_nitrogen_monoxide_in_air", "type": "standard_name", "name": "mole_concentration_of_nitrogen_monoxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrous_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitrous_acid_in_air.json index 9695b88bd..e3e5f522f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrous_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrous_acid_in_air", + "id": "mole_concentration_of_nitrous_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_nitrous_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nitrous_oxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nitrous_oxide_in_air.json index 66aee4867..95eef4054 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nitrous_oxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nitrous_oxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nitrous_oxide_in_air", + "id": "mole_concentration_of_nitrous_oxide_in_air", "type": "standard_name", "name": "mole_concentration_of_nitrous_oxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nmvoc_expressed_as_carbon_in_air.json index d89fbd38d..082366bdf 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nmvoc_expressed_as_carbon_in_air", + "id": "mole_concentration_of_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mole_concentration_of_nmvoc_expressed_as_carbon_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained inA, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_nox_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mole_concentration_of_nox_expressed_as_nitrogen_in_air.json index aa761c2d7..c0a5fa22d 100644 --- a/data_descriptors/standard_name/mole_concentration_of_nox_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_nox_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_nox_expressed_as_nitrogen_in_air", + "id": "mole_concentration_of_nox_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mole_concentration_of_nox_expressed_as_nitrogen_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_noy_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mole_concentration_of_noy_expressed_as_nitrogen_in_air.json index be7704cd8..c1ae1f5a6 100644 --- a/data_descriptors/standard_name/mole_concentration_of_noy_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_noy_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_noy_expressed_as_nitrogen_in_air", + "id": "mole_concentration_of_noy_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mole_concentration_of_noy_expressed_as_nitrogen_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json index 8b9a5e363..1e52ca744 100644 --- a/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Organic detritus are particles of debris from decaying plants and animals.", diff --git a/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json index 8b96c0cb1..728b3abeb 100644 --- a/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_organic_detritus_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Organic detritus are particles of debris from decaying plants and animals.", diff --git a/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water.json index 873dd6ab6..4b0083c95 100644 --- a/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water", + "id": "mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_organic_detritus_expressed_as_silicon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Organic detritus are particles of debris from decaying plants and animals.", diff --git a/data_descriptors/standard_name/mole_concentration_of_ozone_in_air.json b/data_descriptors/standard_name/mole_concentration_of_ozone_in_air.json index 2c849cd51..2e289adb4 100644 --- a/data_descriptors/standard_name/mole_concentration_of_ozone_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_ozone_in_air", + "id": "mole_concentration_of_ozone_in_air", "type": "standard_name", "name": "mole_concentration_of_ozone_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for ozone is O3.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water.json index 8ed0d21af..92a6276c2 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_calcium_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water.json index ed42a7d5e..897d14984 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water.json index 4c655bb66..70a5e49eb 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_iron_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water.json index 286708aa5..fb8b1aba0 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_magnesium_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water.json index 551c5ec28..b648c90fc 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_manganese_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water.json index 195ea3301..5a224dec4 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_phosphorus_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes. Phosphorus means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\".", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water.json index 585eeb9c4..0ad0f7fc7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_potassium_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water.json index 7e5150d0f..fcfd1e0ba 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called\"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water.json index 4fbf4cc67..7069c3226 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_sodium_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water.json index 10e2aa322..b86dd92dc 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_sulfur_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water.json index 0227d4a93..42d5bf484 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water", + "id": "mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_matter_expressed_as_zinc_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water.json index 9161fc1c7..10a9f4e69 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", + "id": "mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water.json index d11fb0ece..b6c09ca15 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water.json index ac753e055..de5aeac9f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", + "id": "mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water.json index a1aeab5a1..9610c532e 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water", + "id": "mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_nitrogen_in_sea_water.json index e65629901..b4cc0cfb7 100644 --- a/data_descriptors/standard_name/mole_concentration_of_particulate_organic_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_particulate_organic_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_particulate_organic_nitrogen_in_sea_water", + "id": "mole_concentration_of_particulate_organic_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_particulate_organic_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Particulate organic nitrogen\" means the sum of all organic nitrogen compounds that are solid, or bound to solid particles. \"Organic nitrogen\", when measured, always refers to all nitrogen incorporated in carbon compounds in the sample. Models may use the term to refer to nitrogen contained in specific groups of organic compounds in which case the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_concentration_of_peroxyacetyl_nitrate_in_air.json b/data_descriptors/standard_name/mole_concentration_of_peroxyacetyl_nitrate_in_air.json index 49bf439c2..02572d75a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_peroxyacetyl_nitrate_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_peroxyacetyl_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_peroxyacetyl_nitrate_in_air", + "id": "mole_concentration_of_peroxyacetyl_nitrate_in_air", "type": "standard_name", "name": "mole_concentration_of_peroxyacetyl_nitrate_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/mole_concentration_of_peroxynitric_acid_in_air.json b/data_descriptors/standard_name/mole_concentration_of_peroxynitric_acid_in_air.json index 5fcb8aadd..ea636a867 100644 --- a/data_descriptors/standard_name/mole_concentration_of_peroxynitric_acid_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_peroxynitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_peroxynitric_acid_in_air", + "id": "mole_concentration_of_peroxynitric_acid_in_air", "type": "standard_name", "name": "mole_concentration_of_peroxynitric_acid_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_phosphate_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_phosphate_in_sea_water.json index 1963555b1..3932bec67 100644 --- a/data_descriptors/standard_name/mole_concentration_of_phosphate_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_phosphate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_phosphate_in_sea_water", + "id": "mole_concentration_of_phosphate_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_phosphate_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", diff --git a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water.json index 959cbc878..e30e92d40 100644 --- a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Standard names also exist for the mole concentration of a number of components that make up the total phytoplankton population, such as diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton and miscellaneous phytoplankton.", diff --git a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water.json index 29ca60761..498705f71 100644 --- a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", + "id": "mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water.json index 19ca5027a..2959df343 100644 --- a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water.json index 1cb8e4658..24b713e59 100644 --- a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", + "id": "mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water.json index cef344572..56f59e65f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", + "id": "mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water.json index 2e3b8136e..7beebc5f9 100644 --- a/data_descriptors/standard_name/mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water.json index ebf6bcd3e..0180a259f 100644 --- a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water", + "id": "mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_preformed_dissolved_inorganic_13C_in_sea_water", "description": "\"Mole concentration\" means the number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon-13\" is the sum of CO3_13C, HCO3_13C and H2CO3_13C. The subduction and subsequent transport of surface water carry into the interior ocean considerable quantities of dissolved inorganic carbon-13, which is entirely independent of biological activity (such as organic decomposition and oxidation) after the water leaves the sea surface. Such dissolved inorganic carbon-13 is termed \u201cpreformed\u201d dissolved inorganic carbon-13 (Redfield,1942).", diff --git a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water.json index 8e1dccedb..c6a4f5541 100644 --- a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water", + "id": "mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_preformed_dissolved_inorganic_carbon_in_sea_water", "description": "\"Mole concentration\" means the number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon\" is the sum of CO3, HCO3 and H2CO3. The subduction and subsequent transport of surface water carry into the interior ocean considerable quantities of dissolved inorganic carbon, which is entirely independent of biological activity (such as organic decomposition and oxidation) after the water leaves the sea surface. Such dissolved inorganic carbon is termed \u201cpreformed\u201d dissolved inorganic carbon (Redfield,1942).", diff --git a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water.json index af7a491a8..662f0e684 100644 --- a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water", + "id": "mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_preformed_dissolved_inorganic_phosphorus_in_sea_water", "description": "\"Mole concentration\" means the number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic phosphorus\" means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid). The subduction and subsequent transport of surface water carry into the interior ocean considerable quantities of nutrients, which are entirely independent of biological activity (such as organic decomposition and oxidation) after the water leaves the sea surface. Such nutrients are termed \u201cpreformed\u201d nutrients (Redfield,1942).", diff --git a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water.json index d01ab5be1..57aed5a19 100644 --- a/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water", + "id": "mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_preformed_dissolved_molecular_oxygen_in_sea_water", "description": "\"Mole concentration\" means the number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The subduction and subsequent transport of surface water carry into the interior ocean considerable quantities of dissolved oxygen, which are entirely independent of biological activity (such as organic decomposition and oxidation) after the water leaves the sea surface. Such dissolved oxygen is termed \u201cpreformed\u201d dissolved oxygen (Redfield,1942).", diff --git a/data_descriptors/standard_name/mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json index 3dc655a46..b5132b72b 100644 --- a/data_descriptors/standard_name/mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_prokaryotes_expressed_as_carbon_in_sea_water", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Prokaryotes\" means all Bacteria and Archaea excluding photosynthetic cyanobacteria such as Synechococcus and Prochlorococcus or other separately named components of the prokaryotic population.", diff --git a/data_descriptors/standard_name/mole_concentration_of_propane_in_air.json b/data_descriptors/standard_name/mole_concentration_of_propane_in_air.json index b7c433bf6..424338df8 100644 --- a/data_descriptors/standard_name/mole_concentration_of_propane_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_propane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_propane_in_air", + "id": "mole_concentration_of_propane_in_air", "type": "standard_name", "name": "mole_concentration_of_propane_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_propene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_propene_in_air.json index ac5020711..23366676c 100644 --- a/data_descriptors/standard_name/mole_concentration_of_propene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_propene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_propene_in_air", + "id": "mole_concentration_of_propene_in_air", "type": "standard_name", "name": "mole_concentration_of_propene_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_radon_in_air.json b/data_descriptors/standard_name/mole_concentration_of_radon_in_air.json index ea4adf681..b12a6e1af 100644 --- a/data_descriptors/standard_name/mole_concentration_of_radon_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_radon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_radon_in_air", + "id": "mole_concentration_of_radon_in_air", "type": "standard_name", "name": "mole_concentration_of_radon_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/mole_concentration_of_silicate_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_silicate_in_sea_water.json index d3c5d4eba..2bc3cf624 100644 --- a/data_descriptors/standard_name/mole_concentration_of_silicate_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_silicate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_silicate_in_sea_water", + "id": "mole_concentration_of_silicate_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_silicate_in_sea_water", "description": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_concentration_of_sulfur_dioxide_in_air.json b/data_descriptors/standard_name/mole_concentration_of_sulfur_dioxide_in_air.json index baf71cd61..65d1267c0 100644 --- a/data_descriptors/standard_name/mole_concentration_of_sulfur_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_sulfur_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_sulfur_dioxide_in_air", + "id": "mole_concentration_of_sulfur_dioxide_in_air", "type": "standard_name", "name": "mole_concentration_of_sulfur_dioxide_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/mole_concentration_of_sulfur_hexafluoride_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_sulfur_hexafluoride_in_sea_water.json index c60dfe0ad..903baaa13 100644 --- a/data_descriptors/standard_name/mole_concentration_of_sulfur_hexafluoride_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_sulfur_hexafluoride_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_sulfur_hexafluoride_in_sea_water", + "id": "mole_concentration_of_sulfur_hexafluoride_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_sulfur_hexafluoride_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of sulfur hexafluoride is SF6.", diff --git a/data_descriptors/standard_name/mole_concentration_of_toluene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_toluene_in_air.json index 2a812c241..03469c13b 100644 --- a/data_descriptors/standard_name/mole_concentration_of_toluene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_toluene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_toluene_in_air", + "id": "mole_concentration_of_toluene_in_air", "type": "standard_name", "name": "mole_concentration_of_toluene_in_air", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/mole_concentration_of_water_vapor_in_air.json b/data_descriptors/standard_name/mole_concentration_of_water_vapor_in_air.json index ba7475962..54aaaf722 100644 --- a/data_descriptors/standard_name/mole_concentration_of_water_vapor_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_water_vapor_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_water_vapor_in_air", + "id": "mole_concentration_of_water_vapor_in_air", "type": "standard_name", "name": "mole_concentration_of_water_vapor_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", diff --git a/data_descriptors/standard_name/mole_concentration_of_xylene_in_air.json b/data_descriptors/standard_name/mole_concentration_of_xylene_in_air.json index 316038c0b..985ae67a2 100644 --- a/data_descriptors/standard_name/mole_concentration_of_xylene_in_air.json +++ b/data_descriptors/standard_name/mole_concentration_of_xylene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_xylene_in_air", + "id": "mole_concentration_of_xylene_in_air", "type": "standard_name", "name": "mole_concentration_of_xylene_in_air", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json index 89c40a482..0e98ec65e 100644 --- a/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", + "id": "mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Standard names also exist for the mole concentration of a number of components that make up the total zooplankton population, such as mesozooplankton, microzooplankton and miscellaneous zooplankton.", diff --git a/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water.json b/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water.json index 17b4ba92d..7be426d7a 100644 --- a/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water", + "id": "mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water", "type": "standard_name", "name": "mole_concentration_of_zooplankton_expressed_as_nitrogen_in_sea_water", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated in terms of B alone, neglecting all other chemical constituents of A. Standard names also exist for the mole concentration of a number of components that make up the total zooplankton population, such as mesozooplankton, and microzooplankton.", diff --git a/data_descriptors/standard_name/mole_content_of_carbon_monoxide_in_atmosphere_layer.json b/data_descriptors/standard_name/mole_content_of_carbon_monoxide_in_atmosphere_layer.json index aea6f948b..e490da728 100644 --- a/data_descriptors/standard_name/mole_content_of_carbon_monoxide_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mole_content_of_carbon_monoxide_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_content_of_carbon_monoxide_in_atmosphere_layer", + "id": "mole_content_of_carbon_monoxide_in_atmosphere_layer", "type": "standard_name", "name": "mole_content_of_carbon_monoxide_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. For the mole content integrated from the surface to the top of the atmosphere, standard names including \"atmosphere_mole_content_of_X\" are used. The chemical formula for carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/mole_content_of_methane_in_atmosphere_layer.json b/data_descriptors/standard_name/mole_content_of_methane_in_atmosphere_layer.json index cc39e05c8..59e322f44 100644 --- a/data_descriptors/standard_name/mole_content_of_methane_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mole_content_of_methane_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_content_of_methane_in_atmosphere_layer", + "id": "mole_content_of_methane_in_atmosphere_layer", "type": "standard_name", "name": "mole_content_of_methane_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. For the mole content integrated from the surface to the top of the atmosphere, standard names including \"atmosphere_mole_content_of_X\" are used. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_content_of_nitrogen_dioxide_in_atmosphere_layer.json b/data_descriptors/standard_name/mole_content_of_nitrogen_dioxide_in_atmosphere_layer.json index cbf652dd6..6927baa38 100644 --- a/data_descriptors/standard_name/mole_content_of_nitrogen_dioxide_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mole_content_of_nitrogen_dioxide_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_content_of_nitrogen_dioxide_in_atmosphere_layer", + "id": "mole_content_of_nitrogen_dioxide_in_atmosphere_layer", "type": "standard_name", "name": "mole_content_of_nitrogen_dioxide_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. For the mole content integrated from the surface to the top of the atmosphere, standard names including \"atmosphere_mole_content_of_X\" are used. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/mole_content_of_ozone_in_atmosphere_layer.json b/data_descriptors/standard_name/mole_content_of_ozone_in_atmosphere_layer.json index a00369f20..d5dab4f5f 100644 --- a/data_descriptors/standard_name/mole_content_of_ozone_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/mole_content_of_ozone_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_content_of_ozone_in_atmosphere_layer", + "id": "mole_content_of_ozone_in_atmosphere_layer", "type": "standard_name", "name": "mole_content_of_ozone_in_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. The \"content_of_X_in_atmosphere_layer\" refers to the vertical integral between two specified levels in the atmosphere. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. For the mole content integrated from the surface to the top of the atmosphere, standard names including \"atmosphere_mole_content_of_X\" are used. The chemical formula for ozone is O3. \"mole_content_of_ozone_in_atmosphere_layer\" is usually measured in Dobson Units which are equivalent to 446.2 micromoles m-2. N.B. Data variables containing column content of ozone can be given the standard name of either equivalent_thickness_at_stp_of_atmosphere_ozone_content or atmosphere_mole_content_of_ozone. The latter name is recommended for consistency with mole content names for chemical species other than ozone.", diff --git a/data_descriptors/standard_name/mole_fraction_of_acetaldehyde_in_air.json b/data_descriptors/standard_name/mole_fraction_of_acetaldehyde_in_air.json index c6df0c461..9aba12017 100644 --- a/data_descriptors/standard_name/mole_fraction_of_acetaldehyde_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_acetaldehyde_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_acetaldehyde_in_air", + "id": "mole_fraction_of_acetaldehyde_in_air", "type": "standard_name", "name": "mole_fraction_of_acetaldehyde_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for acetaldehyde is CH3CHO. The IUPAC name for acetaldehyde is ethanal.", diff --git a/data_descriptors/standard_name/mole_fraction_of_acetic_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_acetic_acid_in_air.json index 9209d62e7..6ece27a6f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_acetic_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_acetic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_acetic_acid_in_air", + "id": "mole_fraction_of_acetic_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_acetic_acid_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for acetic acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/mole_fraction_of_aceto_nitrile_in_air.json b/data_descriptors/standard_name/mole_fraction_of_aceto_nitrile_in_air.json index 0a5665a9f..6cba957ef 100644 --- a/data_descriptors/standard_name/mole_fraction_of_aceto_nitrile_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_aceto_nitrile_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_aceto_nitrile_in_air", + "id": "mole_fraction_of_aceto_nitrile_in_air", "type": "standard_name", "name": "mole_fraction_of_aceto_nitrile_in_air", "description": "\"Mole fraction\" is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for acetonitrile is CH3CN. The IUPAC name for acetonitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/mole_fraction_of_acetone_in_air.json b/data_descriptors/standard_name/mole_fraction_of_acetone_in_air.json index cb69bc20c..b11d6fd38 100644 --- a/data_descriptors/standard_name/mole_fraction_of_acetone_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_acetone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_acetone_in_air", + "id": "mole_fraction_of_acetone_in_air", "type": "standard_name", "name": "mole_fraction_of_acetone_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Acetone is an organic molecule with the chemical formula CH3CH3CO. The IUPAC name for acetone is propan-2-one. Acetone is a member of the group of organic compounds known as ketones. There are standard names for the ketone group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_aldehydes_in_air.json b/data_descriptors/standard_name/mole_fraction_of_aldehydes_in_air.json index 6acc1f456..fd9b88fe2 100644 --- a/data_descriptors/standard_name/mole_fraction_of_aldehydes_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_aldehydes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_aldehydes_in_air", + "id": "mole_fraction_of_aldehydes_in_air", "type": "standard_name", "name": "mole_fraction_of_aldehydes_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Aldehydes are organic compounds with a CHO group; \"aldehydes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for formaldehyde as the simplest member of the aldehydes group.", diff --git a/data_descriptors/standard_name/mole_fraction_of_alkanes_in_air.json b/data_descriptors/standard_name/mole_fraction_of_alkanes_in_air.json index a39b9805f..ebddcd67d 100644 --- a/data_descriptors/standard_name/mole_fraction_of_alkanes_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_alkanes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_alkanes_in_air", + "id": "mole_fraction_of_alkanes_in_air", "type": "standard_name", "name": "mole_fraction_of_alkanes_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Alkanes are saturated hydrocarbons, i.e. they do not contain any chemical double bonds. Alkanes contain only hydrogen and carbon combined in the general proportions C(n)H(2n+2); \"alkanes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkane species, e.g., methane and ethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_alkenes_in_air.json b/data_descriptors/standard_name/mole_fraction_of_alkenes_in_air.json index e06d4eeef..b5287618c 100644 --- a/data_descriptors/standard_name/mole_fraction_of_alkenes_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_alkenes_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_alkenes_in_air", + "id": "mole_fraction_of_alkenes_in_air", "type": "standard_name", "name": "mole_fraction_of_alkenes_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Alkenes are unsaturated hydrocarbons as they contain chemical double bonds between adjacent carbon atoms. \"Hydrocarbon\" means a compound containing hydrogen and carbon. Alkenes contain only hydrogen and carbon combined in the general proportions C(n)H(2n); \"alkenes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkene species, e.g., ethene and propene.", diff --git a/data_descriptors/standard_name/mole_fraction_of_alpha_hexachlorocyclohexane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_alpha_hexachlorocyclohexane_in_air.json index c9836cbff..ab7892c3b 100644 --- a/data_descriptors/standard_name/mole_fraction_of_alpha_hexachlorocyclohexane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_alpha_hexachlorocyclohexane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_alpha_hexachlorocyclohexane_in_air", + "id": "mole_fraction_of_alpha_hexachlorocyclohexane_in_air", "type": "standard_name", "name": "mole_fraction_of_alpha_hexachlorocyclohexane_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_alpha_pinene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_alpha_pinene_in_air.json index 065f8d85e..3d8b8ee22 100644 --- a/data_descriptors/standard_name/mole_fraction_of_alpha_pinene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_alpha_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_alpha_pinene_in_air", + "id": "mole_fraction_of_alpha_pinene_in_air", "type": "standard_name", "name": "mole_fraction_of_alpha_pinene_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for alpha-pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ammonia_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ammonia_in_air.json index 7e0b0594c..8f7592af2 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ammonia_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ammonia_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ammonia_in_air", + "id": "mole_fraction_of_ammonia_in_air", "type": "standard_name", "name": "mole_fraction_of_ammonia_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json index 7bacf6df8..396075c38 100644 --- a/data_descriptors/standard_name/mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mole_fraction_of_anthropogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air.json b/data_descriptors/standard_name/mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air.json index 900acc49d..148be246f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air", + "id": "mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air", "type": "standard_name", "name": "mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Artificial tracer\" means a passive atmospheric tracer that is used to study atmospheric transport and deposition. To specify the length of the tracer lifetime in the atmosphere, a scalar coordinate variable with the standard name of tracer_lifetime should be used.", diff --git a/data_descriptors/standard_name/mole_fraction_of_atomic_bromine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_atomic_bromine_in_air.json index 406ec1177..680b85df0 100644 --- a/data_descriptors/standard_name/mole_fraction_of_atomic_bromine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_atomic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_atomic_bromine_in_air", + "id": "mole_fraction_of_atomic_bromine_in_air", "type": "standard_name", "name": "mole_fraction_of_atomic_bromine_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical symbol of atomic bromine is Br.", diff --git a/data_descriptors/standard_name/mole_fraction_of_atomic_chlorine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_atomic_chlorine_in_air.json index 99dcd5c5b..b3b38ba62 100644 --- a/data_descriptors/standard_name/mole_fraction_of_atomic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_atomic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_atomic_chlorine_in_air", + "id": "mole_fraction_of_atomic_chlorine_in_air", "type": "standard_name", "name": "mole_fraction_of_atomic_chlorine_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical symbol of atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/mole_fraction_of_atomic_nitrogen_in_air.json b/data_descriptors/standard_name/mole_fraction_of_atomic_nitrogen_in_air.json index cd8d55be8..98dfa4cbf 100644 --- a/data_descriptors/standard_name/mole_fraction_of_atomic_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_atomic_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_atomic_nitrogen_in_air", + "id": "mole_fraction_of_atomic_nitrogen_in_air", "type": "standard_name", "name": "mole_fraction_of_atomic_nitrogen_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical symbol of atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/mole_fraction_of_benzene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_benzene_in_air.json index f68ec6b13..2546fae09 100644 --- a/data_descriptors/standard_name/mole_fraction_of_benzene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_benzene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_benzene_in_air", + "id": "mole_fraction_of_benzene_in_air", "type": "standard_name", "name": "mole_fraction_of_benzene_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_beta_pinene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_beta_pinene_in_air.json index a55e017da..baf563229 100644 --- a/data_descriptors/standard_name/mole_fraction_of_beta_pinene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_beta_pinene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_beta_pinene_in_air", + "id": "mole_fraction_of_beta_pinene_in_air", "type": "standard_name", "name": "mole_fraction_of_beta_pinene_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for beta pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json index f35746bfa..67058b716 100644 --- a/data_descriptors/standard_name/mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air", + "id": "mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mole_fraction_of_biogenic_nmvoc_expressed_as_carbon_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes.", diff --git a/data_descriptors/standard_name/mole_fraction_of_bromine_chloride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_bromine_chloride_in_air.json index 68a9190e1..fa31cd7fa 100644 --- a/data_descriptors/standard_name/mole_fraction_of_bromine_chloride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_bromine_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_bromine_chloride_in_air", + "id": "mole_fraction_of_bromine_chloride_in_air", "type": "standard_name", "name": "mole_fraction_of_bromine_chloride_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/mole_fraction_of_bromine_monoxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_bromine_monoxide_in_air.json index c1e2c4876..6e77cb178 100644 --- a/data_descriptors/standard_name/mole_fraction_of_bromine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_bromine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_bromine_monoxide_in_air", + "id": "mole_fraction_of_bromine_monoxide_in_air", "type": "standard_name", "name": "mole_fraction_of_bromine_monoxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/mole_fraction_of_bromine_nitrate_in_air.json b/data_descriptors/standard_name/mole_fraction_of_bromine_nitrate_in_air.json index 7257fcfcf..261b741c8 100644 --- a/data_descriptors/standard_name/mole_fraction_of_bromine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_bromine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_bromine_nitrate_in_air", + "id": "mole_fraction_of_bromine_nitrate_in_air", "type": "standard_name", "name": "mole_fraction_of_bromine_nitrate_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of bromine nitrate is BrONO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_bromochloromethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_bromochloromethane_in_air.json index 0c895dbf2..79ffb4e52 100644 --- a/data_descriptors/standard_name/mole_fraction_of_bromochloromethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_bromochloromethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_bromochloromethane_in_air", + "id": "mole_fraction_of_bromochloromethane_in_air", "type": "standard_name", "name": "mole_fraction_of_bromochloromethane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for bromochloromethane is CH2BrCl. The IUPAC name is bromochloromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_bromodichloromethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_bromodichloromethane_in_air.json index 98179dadf..4c3dbea33 100644 --- a/data_descriptors/standard_name/mole_fraction_of_bromodichloromethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_bromodichloromethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_bromodichloromethane_in_air", + "id": "mole_fraction_of_bromodichloromethane_in_air", "type": "standard_name", "name": "mole_fraction_of_bromodichloromethane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for bromodichloromethane is CHBrCl2. The IUPAC name is bromodichloromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_brox_expressed_as_bromine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_brox_expressed_as_bromine_in_air.json index a50c68667..c1fe4799f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_brox_expressed_as_bromine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_brox_expressed_as_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_brox_expressed_as_bromine_in_air", + "id": "mole_fraction_of_brox_expressed_as_bromine_in_air", "type": "standard_name", "name": "mole_fraction_of_brox_expressed_as_bromine_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_butane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_butane_in_air.json index a4cfc7b5a..ca7791957 100644 --- a/data_descriptors/standard_name/mole_fraction_of_butane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_butane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_butane_in_air", + "id": "mole_fraction_of_butane_in_air", "type": "standard_name", "name": "mole_fraction_of_butane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_air.json index 6074c24af..1fba3e0ed 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbon_dioxide_in_air", + "id": "mole_fraction_of_carbon_dioxide_in_air", "type": "standard_name", "name": "mole_fraction_of_carbon_dioxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_dry_air.json b/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_dry_air.json index 15436a042..04c207952 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_dry_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbon_dioxide_in_dry_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbon_dioxide_in_dry_air", + "id": "mole_fraction_of_carbon_dioxide_in_dry_air", "type": "standard_name", "name": "mole_fraction_of_carbon_dioxide_in_dry_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"in_dry_air\" means that the quantity is calculated as the total number of particles of X divided by the number of dry air particles, i.e. the effect of water vapor is excluded. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_air.json index b964b818d..1a77789f6 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbon_monoxide_in_air", + "id": "mole_fraction_of_carbon_monoxide_in_air", "type": "standard_name", "name": "mole_fraction_of_carbon_monoxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_dry_air.json b/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_dry_air.json index 5495ebd88..8f57327dd 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_dry_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbon_monoxide_in_dry_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbon_monoxide_in_dry_air", + "id": "mole_fraction_of_carbon_monoxide_in_dry_air", "type": "standard_name", "name": "mole_fraction_of_carbon_monoxide_in_dry_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"in_dry_air\" means that the quantity is calculated as the total number of particles of X divided by the number of dry air particles, i.e. the effect of water vapor is excluded. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbon_tetrachloride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_carbon_tetrachloride_in_air.json index 1ec2229bc..16e953ce9 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbon_tetrachloride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbon_tetrachloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbon_tetrachloride_in_air", + "id": "mole_fraction_of_carbon_tetrachloride_in_air", "type": "standard_name", "name": "mole_fraction_of_carbon_tetrachloride_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbon_tetrafluoride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_carbon_tetrafluoride_in_air.json index 88a81bb4f..9a0baec32 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbon_tetrafluoride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbon_tetrafluoride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbon_tetrafluoride_in_air", + "id": "mole_fraction_of_carbon_tetrafluoride_in_air", "type": "standard_name", "name": "mole_fraction_of_carbon_tetrafluoride_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for carbon tetrafluoride, also called PFC14, is CF4. The IUPAC name for carbon tetrafluoride is tetrafluoromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbonyl_fluoride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_carbonyl_fluoride_in_air.json index c92f4b3d2..e41ccd2dd 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbonyl_fluoride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbonyl_fluoride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbonyl_fluoride_in_air", + "id": "mole_fraction_of_carbonyl_fluoride_in_air", "type": "standard_name", "name": "mole_fraction_of_carbonyl_fluoride_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of carbonyl fluoride is COF2. The IUPAC name for carbonyl fluoride is carbonyl difluoride.", diff --git a/data_descriptors/standard_name/mole_fraction_of_carbonyl_sulfide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_carbonyl_sulfide_in_air.json index cf5809d43..e171eafe4 100644 --- a/data_descriptors/standard_name/mole_fraction_of_carbonyl_sulfide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_carbonyl_sulfide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_carbonyl_sulfide_in_air", + "id": "mole_fraction_of_carbonyl_sulfide_in_air", "type": "standard_name", "name": "mole_fraction_of_carbonyl_sulfide_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for carbonyl sulfide is COS. The IUPAC name for carbonyl sulfide is carbon oxide sulfide.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc113_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc113_in_air.json index 732904274..cc76f9135 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc113_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc113_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc113_in_air", + "id": "mole_fraction_of_cfc113_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc113_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc113a_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc113a_in_air.json index 7e4a535c8..db86906e4 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc113a_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc113a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc113a_in_air", + "id": "mole_fraction_of_cfc113a_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc113a_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc114_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc114_in_air.json index 538fc7deb..0c3b77c40 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc114_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc114_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc114_in_air", + "id": "mole_fraction_of_cfc114_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc114_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc115_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc115_in_air.json index e1ad6f47c..031c94e22 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc115_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc115_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc115_in_air", + "id": "mole_fraction_of_cfc115_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc115_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc11_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc11_in_air.json index 18319e279..3d7da5d0e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc11_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc11_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc11_in_air", + "id": "mole_fraction_of_cfc11_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc11_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc12_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc12_in_air.json index 6d9fb8bbc..54692cf36 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc12_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc12_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc12_in_air", + "id": "mole_fraction_of_cfc12_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc12_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_cfc13_in_air.json b/data_descriptors/standard_name/mole_fraction_of_cfc13_in_air.json index be72d2a83..50b49e153 100644 --- a/data_descriptors/standard_name/mole_fraction_of_cfc13_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_cfc13_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_cfc13_in_air", + "id": "mole_fraction_of_cfc13_in_air", "type": "standard_name", "name": "mole_fraction_of_cfc13_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for CFC13 is CF3Cl. The IUPAC name for CFC13 is chloro(trifluoro)methane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_chlorine_dioxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_chlorine_dioxide_in_air.json index d4772c06d..d82a310cc 100644 --- a/data_descriptors/standard_name/mole_fraction_of_chlorine_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_chlorine_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_chlorine_dioxide_in_air", + "id": "mole_fraction_of_chlorine_dioxide_in_air", "type": "standard_name", "name": "mole_fraction_of_chlorine_dioxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/mole_fraction_of_chlorine_monoxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_chlorine_monoxide_in_air.json index fbb66819c..e92476232 100644 --- a/data_descriptors/standard_name/mole_fraction_of_chlorine_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_chlorine_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_chlorine_monoxide_in_air", + "id": "mole_fraction_of_chlorine_monoxide_in_air", "type": "standard_name", "name": "mole_fraction_of_chlorine_monoxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/mole_fraction_of_chlorine_nitrate_in_air.json b/data_descriptors/standard_name/mole_fraction_of_chlorine_nitrate_in_air.json index 3930c0907..474bfa43a 100644 --- a/data_descriptors/standard_name/mole_fraction_of_chlorine_nitrate_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_chlorine_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_chlorine_nitrate_in_air", + "id": "mole_fraction_of_chlorine_nitrate_in_air", "type": "standard_name", "name": "mole_fraction_of_chlorine_nitrate_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_chloroform_in_air.json b/data_descriptors/standard_name/mole_fraction_of_chloroform_in_air.json index b419ce500..16164f403 100644 --- a/data_descriptors/standard_name/mole_fraction_of_chloroform_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_chloroform_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_chloroform_in_air", + "id": "mole_fraction_of_chloroform_in_air", "type": "standard_name", "name": "mole_fraction_of_chloroform_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for chloroform is CHCl3. The IUPAC name for chloroform is trichloromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_clox_expressed_as_chlorine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_clox_expressed_as_chlorine_in_air.json index e61cd9db1..64c3e3b63 100644 --- a/data_descriptors/standard_name/mole_fraction_of_clox_expressed_as_chlorine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_clox_expressed_as_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_clox_expressed_as_chlorine_in_air", + "id": "mole_fraction_of_clox_expressed_as_chlorine_in_air", "type": "standard_name", "name": "mole_fraction_of_clox_expressed_as_chlorine_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dibromochloromethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dibromochloromethane_in_air.json index a0be432e8..707d0f51c 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dibromochloromethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dibromochloromethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dibromochloromethane_in_air", + "id": "mole_fraction_of_dibromochloromethane_in_air", "type": "standard_name", "name": "mole_fraction_of_dibromochloromethane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for dibromochloromethane is CHBr2Cl. The IUPAC name is dibromochloromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dibromomethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dibromomethane_in_air.json index af393ccdf..3d0f83d78 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dibromomethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dibromomethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dibromomethane_in_air", + "id": "mole_fraction_of_dibromomethane_in_air", "type": "standard_name", "name": "mole_fraction_of_dibromomethane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for dibromomethane is CH2Br2. The IUPAC name is dibromomethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dichlorine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dichlorine_in_air.json index aad095e13..1d8176ca5 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dichlorine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dichlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dichlorine_in_air", + "id": "mole_fraction_of_dichlorine_in_air", "type": "standard_name", "name": "mole_fraction_of_dichlorine_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Dichlorine is the molecular form of elemental chlorine with the chemical formula Cl2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dichlorine_peroxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dichlorine_peroxide_in_air.json index ac87926c9..df7d07174 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dichlorine_peroxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dichlorine_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dichlorine_peroxide_in_air", + "id": "mole_fraction_of_dichlorine_peroxide_in_air", "type": "standard_name", "name": "mole_fraction_of_dichlorine_peroxide_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dichloromethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dichloromethane_in_air.json index a8068b3da..901ff262c 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dichloromethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dichloromethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dichloromethane_in_air", + "id": "mole_fraction_of_dichloromethane_in_air", "type": "standard_name", "name": "mole_fraction_of_dichloromethane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for dichloromethane is CH2Cl2. The IUPAC name is dichloromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dimethyl_sulfide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dimethyl_sulfide_in_air.json index 300ead216..85161ed8d 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dimethyl_sulfide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dimethyl_sulfide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dimethyl_sulfide_in_air", + "id": "mole_fraction_of_dimethyl_sulfide_in_air", "type": "standard_name", "name": "mole_fraction_of_dimethyl_sulfide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_dinitrogen_pentoxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_dinitrogen_pentoxide_in_air.json index 0402f75d4..354754dd4 100644 --- a/data_descriptors/standard_name/mole_fraction_of_dinitrogen_pentoxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_dinitrogen_pentoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_dinitrogen_pentoxide_in_air", + "id": "mole_fraction_of_dinitrogen_pentoxide_in_air", "type": "standard_name", "name": "mole_fraction_of_dinitrogen_pentoxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ethane_in_air.json index fa14c6b6c..42dab2004 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ethane_in_air", + "id": "mole_fraction_of_ethane_in_air", "type": "standard_name", "name": "mole_fraction_of_ethane_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ethanol_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ethanol_in_air.json index cb4b01fe9..780afa1a7 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ethanol_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ethanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ethanol_in_air", + "id": "mole_fraction_of_ethanol_in_air", "type": "standard_name", "name": "mole_fraction_of_ethanol_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ethene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ethene_in_air.json index a52fd3387..b372dd0ef 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ethene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ethene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ethene_in_air", + "id": "mole_fraction_of_ethene_in_air", "type": "standard_name", "name": "mole_fraction_of_ethene_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ethyne_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ethyne_in_air.json index 9a45cf601..0a1419654 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ethyne_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ethyne_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ethyne_in_air", + "id": "mole_fraction_of_ethyne_in_air", "type": "standard_name", "name": "mole_fraction_of_ethyne_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_formaldehyde_in_air.json b/data_descriptors/standard_name/mole_fraction_of_formaldehyde_in_air.json index 002165254..0f587e77e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_formaldehyde_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_formaldehyde_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_formaldehyde_in_air", + "id": "mole_fraction_of_formaldehyde_in_air", "type": "standard_name", "name": "mole_fraction_of_formaldehyde_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_formic_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_formic_acid_in_air.json index cb9641936..98cb0f986 100644 --- a/data_descriptors/standard_name/mole_fraction_of_formic_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_formic_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_formic_acid_in_air", + "id": "mole_fraction_of_formic_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_formic_acid_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/mole_fraction_of_gaseous_divalent_mercury_in_air.json b/data_descriptors/standard_name/mole_fraction_of_gaseous_divalent_mercury_in_air.json index 7fc9d65b7..3951bbfec 100644 --- a/data_descriptors/standard_name/mole_fraction_of_gaseous_divalent_mercury_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_gaseous_divalent_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_gaseous_divalent_mercury_in_air", + "id": "mole_fraction_of_gaseous_divalent_mercury_in_air", "type": "standard_name", "name": "mole_fraction_of_gaseous_divalent_mercury_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/mole_fraction_of_gaseous_elemental_mercury_in_air.json b/data_descriptors/standard_name/mole_fraction_of_gaseous_elemental_mercury_in_air.json index 16e799ff9..1039a07c1 100644 --- a/data_descriptors/standard_name/mole_fraction_of_gaseous_elemental_mercury_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_gaseous_elemental_mercury_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_gaseous_elemental_mercury_in_air", + "id": "mole_fraction_of_gaseous_elemental_mercury_in_air", "type": "standard_name", "name": "mole_fraction_of_gaseous_elemental_mercury_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_glyoxal_in_air.json b/data_descriptors/standard_name/mole_fraction_of_glyoxal_in_air.json index 7c086d11d..80e12299c 100644 --- a/data_descriptors/standard_name/mole_fraction_of_glyoxal_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_glyoxal_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_glyoxal_in_air", + "id": "mole_fraction_of_glyoxal_in_air", "type": "standard_name", "name": "mole_fraction_of_glyoxal_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for glyoxal is CHOCHO. The IUPAC name for glyoxal is ethanedial.", diff --git a/data_descriptors/standard_name/mole_fraction_of_halon1202_in_air.json b/data_descriptors/standard_name/mole_fraction_of_halon1202_in_air.json index 27e84eda7..ec99aa6c2 100644 --- a/data_descriptors/standard_name/mole_fraction_of_halon1202_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_halon1202_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_halon1202_in_air", + "id": "mole_fraction_of_halon1202_in_air", "type": "standard_name", "name": "mole_fraction_of_halon1202_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_halon1211_in_air.json b/data_descriptors/standard_name/mole_fraction_of_halon1211_in_air.json index e3d6a7bf0..8013eebd1 100644 --- a/data_descriptors/standard_name/mole_fraction_of_halon1211_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_halon1211_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_halon1211_in_air", + "id": "mole_fraction_of_halon1211_in_air", "type": "standard_name", "name": "mole_fraction_of_halon1211_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_halon1301_in_air.json b/data_descriptors/standard_name/mole_fraction_of_halon1301_in_air.json index 681bacd50..411315699 100644 --- a/data_descriptors/standard_name/mole_fraction_of_halon1301_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_halon1301_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_halon1301_in_air", + "id": "mole_fraction_of_halon1301_in_air", "type": "standard_name", "name": "mole_fraction_of_halon1301_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_halon2402_in_air.json b/data_descriptors/standard_name/mole_fraction_of_halon2402_in_air.json index f7535ce39..9b2cf0582 100644 --- a/data_descriptors/standard_name/mole_fraction_of_halon2402_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_halon2402_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_halon2402_in_air", + "id": "mole_fraction_of_halon2402_in_air", "type": "standard_name", "name": "mole_fraction_of_halon2402_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcc140a_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcc140a_in_air.json index 10517b3e0..41591cf50 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcc140a_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcc140a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcc140a_in_air", + "id": "mole_fraction_of_hcc140a_in_air", "type": "standard_name", "name": "mole_fraction_of_hcc140a_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcfc124_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcfc124_in_air.json index be4dc00c1..5ab7979e9 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcfc124_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcfc124_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcfc124_in_air", + "id": "mole_fraction_of_hcfc124_in_air", "type": "standard_name", "name": "mole_fraction_of_hcfc124_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hcfc124 is C2HClF4. The IUPAC name for hcfc124 is 1-chloro-1,2,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcfc132b_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcfc132b_in_air.json index 3d1fe19d6..fdeda03c2 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcfc132b_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcfc132b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcfc132b_in_air", + "id": "mole_fraction_of_hcfc132b_in_air", "type": "standard_name", "name": "mole_fraction_of_hcfc132b_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC132b is CH2ClCClF2. The IUPAC name for HCFC132b is 1,2-dichloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcfc133a_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcfc133a_in_air.json index c9501739c..dfc4991cc 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcfc133a_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcfc133a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcfc133a_in_air", + "id": "mole_fraction_of_hcfc133a_in_air", "type": "standard_name", "name": "mole_fraction_of_hcfc133a_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC133a is CH2ClCF3. The IUPAC name for HCFC133a is 2-chloro-1,1,1-trifluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcfc141b_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcfc141b_in_air.json index e04fc56d1..a45619ba4 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcfc141b_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcfc141b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcfc141b_in_air", + "id": "mole_fraction_of_hcfc141b_in_air", "type": "standard_name", "name": "mole_fraction_of_hcfc141b_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcfc142b_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcfc142b_in_air.json index fc1a3da88..8f68733c2 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcfc142b_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcfc142b_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcfc142b_in_air", + "id": "mole_fraction_of_hcfc142b_in_air", "type": "standard_name", "name": "mole_fraction_of_hcfc142b_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hcfc22_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hcfc22_in_air.json index 07f1eba9f..1c98a7f8e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hcfc22_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hcfc22_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hcfc22_in_air", + "id": "mole_fraction_of_hcfc22_in_air", "type": "standard_name", "name": "mole_fraction_of_hcfc22_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hexachlorobiphenyl_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hexachlorobiphenyl_in_air.json index 51d9c92f4..b505efc66 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hexachlorobiphenyl_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hexachlorobiphenyl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hexachlorobiphenyl_in_air", + "id": "mole_fraction_of_hexachlorobiphenyl_in_air", "type": "standard_name", "name": "mole_fraction_of_hexachlorobiphenyl_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc125_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc125_in_air.json index b26ca5bc2..e96506281 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc125_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc125_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc125_in_air", + "id": "mole_fraction_of_hfc125_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc125_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc125 is CF3CF2H. The IUPAC name for hfc125 is 1,1,1,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc134a_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc134a_in_air.json index 595ba0a71..1d8920f48 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc134a_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc134a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc134a_in_air", + "id": "mole_fraction_of_hfc134a_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc134a_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc134a is CF3CFH2. The IUPAC name for hfc134a is 1,1,1,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc143a_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc143a_in_air.json index f1209a9fd..10a2ccc79 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc143a_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc143a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc143a_in_air", + "id": "mole_fraction_of_hfc143a_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc143a_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc143a is CF3CH3. The IUPAC name for hfc143a is 1,1,1-trifluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc152a_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc152a_in_air.json index 312e1555a..2c638e084 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc152a_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc152a_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc152a_in_air", + "id": "mole_fraction_of_hfc152a_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc152a_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc152a is CF2HCH3. The IUPAC name for hfc152a is 1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc227ea_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc227ea_in_air.json index fe86859a4..8a5bbfdc0 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc227ea_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc227ea_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc227ea_in_air", + "id": "mole_fraction_of_hfc227ea_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc227ea_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc227ea is C3HF7. The IUPAC name for hfc227ea is 1,1,1,2,3,3,3-heptafluoropropane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc236fa_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc236fa_in_air.json index a37efa734..5dc8f5480 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc236fa_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc236fa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc236fa_in_air", + "id": "mole_fraction_of_hfc236fa_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc236fa_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc236fa is C3H2F6. The IUPAC name for hfc236fa is 1,1,1,3,3,3-hexafluoropropane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc23_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc23_in_air.json index d3967ca29..3ae220407 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc23_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc23_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc23_in_air", + "id": "mole_fraction_of_hfc23_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc23_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc23 is CF3H. The IUPAC name for hfc23 is trifluoromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc245fa_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc245fa_in_air.json index beddd075f..5861768bb 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc245fa_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc245fa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc245fa_in_air", + "id": "mole_fraction_of_hfc245fa_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc245fa_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc245fa is C3H3F5. The IUPAC name for hfc245fa is 1,1,1,3,3-pentafluoropropane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc32_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc32_in_air.json index 2ce91e85e..e9d38bd42 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc32_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc32_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc32_in_air", + "id": "mole_fraction_of_hfc32_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc32_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc32 is CF2H2. The IUPAC name for hfc32 is difluoromethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc365mfc_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc365mfc_in_air.json index 5a8dc8959..3ca36c54d 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc365mfc_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc365mfc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc365mfc_in_air", + "id": "mole_fraction_of_hfc365mfc_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc365mfc_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc365mfc is C4H5F5. The IUPAC name for hfc365mfc is 1,1,1,3,3-pentafluorobutane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hfc4310mee_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hfc4310mee_in_air.json index 88f3e27c8..1c0ab8bb9 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hfc4310mee_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hfc4310mee_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hfc4310mee_in_air", + "id": "mole_fraction_of_hfc4310mee_in_air", "type": "standard_name", "name": "mole_fraction_of_hfc4310mee_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hfc4310mee is C5H2F10. The IUPAC name for hfc4310mee is 1,1,1,2,2,3,4,5,5,5-decafluoropentane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hox_expressed_as_hydrogen_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hox_expressed_as_hydrogen_in_air.json index 6c8bca26f..29d6cd9b1 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hox_expressed_as_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hox_expressed_as_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hox_expressed_as_hydrogen_in_air", + "id": "mole_fraction_of_hox_expressed_as_hydrogen_in_air", "type": "standard_name", "name": "mole_fraction_of_hox_expressed_as_hydrogen_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"HOx\" means a combination of two radical species containing hydrogen and oxygen: OH and HO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydrogen_bromide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydrogen_bromide_in_air.json index d60c2eb1f..e0b451a72 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydrogen_bromide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydrogen_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydrogen_bromide_in_air", + "id": "mole_fraction_of_hydrogen_bromide_in_air", "type": "standard_name", "name": "mole_fraction_of_hydrogen_bromide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydrogen_chloride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydrogen_chloride_in_air.json index d390caef0..a3b718616 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydrogen_chloride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydrogen_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydrogen_chloride_in_air", + "id": "mole_fraction_of_hydrogen_chloride_in_air", "type": "standard_name", "name": "mole_fraction_of_hydrogen_chloride_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydrogen_cyanide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydrogen_cyanide_in_air.json index de94b4c32..6b9332e0b 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydrogen_cyanide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydrogen_cyanide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydrogen_cyanide_in_air", + "id": "mole_fraction_of_hydrogen_cyanide_in_air", "type": "standard_name", "name": "mole_fraction_of_hydrogen_cyanide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydrogen_peroxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydrogen_peroxide_in_air.json index bf12a5cb9..5189b35b9 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydrogen_peroxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydrogen_peroxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydrogen_peroxide_in_air", + "id": "mole_fraction_of_hydrogen_peroxide_in_air", "type": "standard_name", "name": "mole_fraction_of_hydrogen_peroxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydrogen peroxide is H202.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydrogen_sulfide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydrogen_sulfide_in_air.json index 3eb2cb230..4412333bf 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydrogen_sulfide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydrogen_sulfide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydrogen_sulfide_in_air", + "id": "mole_fraction_of_hydrogen_sulfide_in_air", "type": "standard_name", "name": "mole_fraction_of_hydrogen_sulfide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of hydrogen sulfide is H2S.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydroperoxyl_radical_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydroperoxyl_radical_in_air.json index 436ebf32f..d1eb02551 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydroperoxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydroperoxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydroperoxyl_radical_in_air", + "id": "mole_fraction_of_hydroperoxyl_radical_in_air", "type": "standard_name", "name": "mole_fraction_of_hydroperoxyl_radical_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydroperoxyl radical is HO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hydroxyl_radical_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hydroxyl_radical_in_air.json index 896e33b92..7177fad2e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hydroxyl_radical_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hydroxyl_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hydroxyl_radical_in_air", + "id": "mole_fraction_of_hydroxyl_radical_in_air", "type": "standard_name", "name": "mole_fraction_of_hydroxyl_radical_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hypobromous_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hypobromous_acid_in_air.json index 52deb5974..f17c74f44 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hypobromous_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hypobromous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hypobromous_acid_in_air", + "id": "mole_fraction_of_hypobromous_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_hypobromous_acid_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/mole_fraction_of_hypochlorous_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_hypochlorous_acid_in_air.json index 30d498b3f..e3269dd85 100644 --- a/data_descriptors/standard_name/mole_fraction_of_hypochlorous_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_hypochlorous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_hypochlorous_acid_in_air", + "id": "mole_fraction_of_hypochlorous_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_hypochlorous_acid_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/mole_fraction_of_inorganic_bromine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_inorganic_bromine_in_air.json index 7fd6c351d..f7aeea81e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_inorganic_bromine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_inorganic_bromine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_inorganic_bromine_in_air", + "id": "mole_fraction_of_inorganic_bromine_in_air", "type": "standard_name", "name": "mole_fraction_of_inorganic_bromine_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of bromine containing source gases (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_inorganic_chlorine_in_air.json b/data_descriptors/standard_name/mole_fraction_of_inorganic_chlorine_in_air.json index 8ef8aeb16..a07336da3 100644 --- a/data_descriptors/standard_name/mole_fraction_of_inorganic_chlorine_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_inorganic_chlorine_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_inorganic_chlorine_in_air", + "id": "mole_fraction_of_inorganic_chlorine_in_air", "type": "standard_name", "name": "mole_fraction_of_inorganic_chlorine_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. \"Inorganic chlorine\",sometimes referred to as Cly, describes a family of chemical species which result from the degradation of chlorine-containing source gases (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea-salt and other aerosols. mole_fraction_of_inorganic_chlorine is the sum of all species belonging to the family that are represented within a given model.", diff --git a/data_descriptors/standard_name/mole_fraction_of_isoprene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_isoprene_in_air.json index 8561d11f0..71607a978 100644 --- a/data_descriptors/standard_name/mole_fraction_of_isoprene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_isoprene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_isoprene_in_air", + "id": "mole_fraction_of_isoprene_in_air", "type": "standard_name", "name": "mole_fraction_of_isoprene_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_limonene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_limonene_in_air.json index 8984edfd2..095ef664b 100644 --- a/data_descriptors/standard_name/mole_fraction_of_limonene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_limonene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_limonene_in_air", + "id": "mole_fraction_of_limonene_in_air", "type": "standard_name", "name": "mole_fraction_of_limonene_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methane_in_air.json index 1b7d8b37a..08f4156bf 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methane_in_air", + "id": "mole_fraction_of_methane_in_air", "type": "standard_name", "name": "mole_fraction_of_methane_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methane_in_dry_air.json b/data_descriptors/standard_name/mole_fraction_of_methane_in_dry_air.json index af8ce7dda..eb77b1763 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methane_in_dry_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methane_in_dry_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methane_in_dry_air", + "id": "mole_fraction_of_methane_in_dry_air", "type": "standard_name", "name": "mole_fraction_of_methane_in_dry_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"in_dry_air\" means that the quantity is calculated as the number of particles of X divided by the number of dry air particles, i.e. the effect of water vapor is excluded. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methanol_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methanol_in_air.json index 783f42d54..f6813186a 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methanol_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methanol_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methanol_in_air", + "id": "mole_fraction_of_methanol_in_air", "type": "standard_name", "name": "mole_fraction_of_methanol_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methyl_bromide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methyl_bromide_in_air.json index 2588769d8..b56d2822f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methyl_bromide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methyl_bromide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methyl_bromide_in_air", + "id": "mole_fraction_of_methyl_bromide_in_air", "type": "standard_name", "name": "mole_fraction_of_methyl_bromide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of methyl bromide is CH3Br.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methyl_chloride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methyl_chloride_in_air.json index 79ee2a5ee..162db139e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methyl_chloride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methyl_chloride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methyl_chloride_in_air", + "id": "mole_fraction_of_methyl_chloride_in_air", "type": "standard_name", "name": "mole_fraction_of_methyl_chloride_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of methyl chloride is CH3Cl.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methyl_hydroperoxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methyl_hydroperoxide_in_air.json index 40b4cba49..564f9f7dc 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methyl_hydroperoxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methyl_hydroperoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methyl_hydroperoxide_in_air", + "id": "mole_fraction_of_methyl_hydroperoxide_in_air", "type": "standard_name", "name": "mole_fraction_of_methyl_hydroperoxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methyl_peroxy_radical_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methyl_peroxy_radical_in_air.json index e9b1b3b3c..6fab19d76 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methyl_peroxy_radical_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methyl_peroxy_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methyl_peroxy_radical_in_air", + "id": "mole_fraction_of_methyl_peroxy_radical_in_air", "type": "standard_name", "name": "mole_fraction_of_methyl_peroxy_radical_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for methyl peroxy radical is CH3O2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_methylglyoxal_in_air.json b/data_descriptors/standard_name/mole_fraction_of_methylglyoxal_in_air.json index f06ee2ec8..d23b68de9 100644 --- a/data_descriptors/standard_name/mole_fraction_of_methylglyoxal_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_methylglyoxal_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_methylglyoxal_in_air", + "id": "mole_fraction_of_methylglyoxal_in_air", "type": "standard_name", "name": "mole_fraction_of_methylglyoxal_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Methylglyoxal is an organic molecule with the chemical formula CH3COCHO. It is also called pyruvaldehyde or 2-oxopropanal.", diff --git a/data_descriptors/standard_name/mole_fraction_of_molecular_hydrogen_in_air.json b/data_descriptors/standard_name/mole_fraction_of_molecular_hydrogen_in_air.json index e5545a353..ce71d4b69 100644 --- a/data_descriptors/standard_name/mole_fraction_of_molecular_hydrogen_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_molecular_hydrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_molecular_hydrogen_in_air", + "id": "mole_fraction_of_molecular_hydrogen_in_air", "type": "standard_name", "name": "mole_fraction_of_molecular_hydrogen_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrate_radical_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrate_radical_in_air.json index 7d6be795f..9030c1b9d 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrate_radical_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrate_radical_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrate_radical_in_air", + "id": "mole_fraction_of_nitrate_radical_in_air", "type": "standard_name", "name": "mole_fraction_of_nitrate_radical_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitric_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitric_acid_in_air.json index fa086592e..47261c42c 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitric_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitric_acid_in_air", + "id": "mole_fraction_of_nitric_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_nitric_acid_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json index f598bc47f..e347e9142 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", + "id": "mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "mole_fraction_of_nitric_acid_trihydrate_ambient_aerosol_particles_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The chemical formula for nitric acid is HNO3. Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrogen_dioxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrogen_dioxide_in_air.json index cfad74bba..4a8c42ff8 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrogen_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrogen_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrogen_dioxide_in_air", + "id": "mole_fraction_of_nitrogen_dioxide_in_air", "type": "standard_name", "name": "mole_fraction_of_nitrogen_dioxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrogen_monoxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrogen_monoxide_in_air.json index d2da12c55..5a0676e5e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrogen_monoxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrogen_monoxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrogen_monoxide_in_air", + "id": "mole_fraction_of_nitrogen_monoxide_in_air", "type": "standard_name", "name": "mole_fraction_of_nitrogen_monoxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrogen_trifluoride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrogen_trifluoride_in_air.json index 79788dd56..6f286304b 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrogen_trifluoride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrogen_trifluoride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrogen_trifluoride_in_air", + "id": "mole_fraction_of_nitrogen_trifluoride_in_air", "type": "standard_name", "name": "mole_fraction_of_nitrogen_trifluoride_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrogen trifluoride is NF3. Nitrogen trifluoride is the IUPAC name.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrous_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrous_acid_in_air.json index 0a96072bb..f1f6f65cd 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrous_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrous_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrous_acid_in_air", + "id": "mole_fraction_of_nitrous_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_nitrous_acid_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_air.json index a80c94bef..22a57f706 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrous_oxide_in_air", + "id": "mole_fraction_of_nitrous_oxide_in_air", "type": "standard_name", "name": "mole_fraction_of_nitrous_oxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_dry_air.json b/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_dry_air.json index 33af9cca8..e3b59f1d9 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_dry_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nitrous_oxide_in_dry_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nitrous_oxide_in_dry_air", + "id": "mole_fraction_of_nitrous_oxide_in_dry_air", "type": "standard_name", "name": "mole_fraction_of_nitrous_oxide_in_dry_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"in_dry_air\" means that the quantity is calculated as the number of particles of X divided by the number of dry air particles, i.e. the effect of water vapor is excluded. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nmvoc_expressed_as_carbon_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nmvoc_expressed_as_carbon_in_air.json index 4454a2578..cdb08e284 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nmvoc_expressed_as_carbon_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nmvoc_expressed_as_carbon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nmvoc_expressed_as_carbon_in_air", + "id": "mole_fraction_of_nmvoc_expressed_as_carbon_in_air", "type": "standard_name", "name": "mole_fraction_of_nmvoc_expressed_as_carbon_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_fraction_of_nox_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mole_fraction_of_nox_expressed_as_nitrogen_in_air.json index c19e72d49..99ff47c62 100644 --- a/data_descriptors/standard_name/mole_fraction_of_nox_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_nox_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_nox_expressed_as_nitrogen_in_air", + "id": "mole_fraction_of_nox_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mole_fraction_of_nox_expressed_as_nitrogen_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2.", diff --git a/data_descriptors/standard_name/mole_fraction_of_noy_expressed_as_nitrogen_in_air.json b/data_descriptors/standard_name/mole_fraction_of_noy_expressed_as_nitrogen_in_air.json index 38aeda86b..c597deb51 100644 --- a/data_descriptors/standard_name/mole_fraction_of_noy_expressed_as_nitrogen_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_noy_expressed_as_nitrogen_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_noy_expressed_as_nitrogen_in_air", + "id": "mole_fraction_of_noy_expressed_as_nitrogen_in_air", "type": "standard_name", "name": "mole_fraction_of_noy_expressed_as_nitrogen_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_fraction_of_organic_nitrates_in_air.json b/data_descriptors/standard_name/mole_fraction_of_organic_nitrates_in_air.json index cf3059b3f..b56956b6f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_organic_nitrates_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_organic_nitrates_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_organic_nitrates_in_air", + "id": "mole_fraction_of_organic_nitrates_in_air", "type": "standard_name", "name": "mole_fraction_of_organic_nitrates_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Organic nitrates are nitrogen-containing compounds having the general formula RONO2, where R is an alkyl (or organic) group; \"organic_nitrates\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ox_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ox_in_air.json index bb0905470..36787aa40 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ox_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ox_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ox_in_air", + "id": "mole_fraction_of_ox_in_air", "type": "standard_name", "name": "mole_fraction_of_ox_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The term \"ox\" means a combination of three radical species containing 1 or 3 oxygen atoms: O + O1d + O3.", diff --git a/data_descriptors/standard_name/mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/mole_fraction_of_ozone_in_air.json index 0027847e8..f37535ecd 100644 --- a/data_descriptors/standard_name/mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_ozone_in_air", + "id": "mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "mole_fraction_of_ozone_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_perchloroethene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_perchloroethene_in_air.json index 046e87bc3..5cf865695 100644 --- a/data_descriptors/standard_name/mole_fraction_of_perchloroethene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_perchloroethene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_perchloroethene_in_air", + "id": "mole_fraction_of_perchloroethene_in_air", "type": "standard_name", "name": "mole_fraction_of_perchloroethene_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for perchloroethene is CCl2CCl2. The IUPAC name for perchloroethene is tetrachloroethene.", diff --git a/data_descriptors/standard_name/mole_fraction_of_peroxyacetyl_nitrate_in_air.json b/data_descriptors/standard_name/mole_fraction_of_peroxyacetyl_nitrate_in_air.json index 322961df5..f725ae71e 100644 --- a/data_descriptors/standard_name/mole_fraction_of_peroxyacetyl_nitrate_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_peroxyacetyl_nitrate_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_peroxyacetyl_nitrate_in_air", + "id": "mole_fraction_of_peroxyacetyl_nitrate_in_air", "type": "standard_name", "name": "mole_fraction_of_peroxyacetyl_nitrate_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_peroxynitric_acid_in_air.json b/data_descriptors/standard_name/mole_fraction_of_peroxynitric_acid_in_air.json index b498442bb..c5e2cdddb 100644 --- a/data_descriptors/standard_name/mole_fraction_of_peroxynitric_acid_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_peroxynitric_acid_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_peroxynitric_acid_in_air", + "id": "mole_fraction_of_peroxynitric_acid_in_air", "type": "standard_name", "name": "mole_fraction_of_peroxynitric_acid_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of peroxynitric acid is HNO4.", diff --git a/data_descriptors/standard_name/mole_fraction_of_pfc116_in_air.json b/data_descriptors/standard_name/mole_fraction_of_pfc116_in_air.json index 61fb0bcd6..3a24e8ffe 100644 --- a/data_descriptors/standard_name/mole_fraction_of_pfc116_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_pfc116_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_pfc116_in_air", + "id": "mole_fraction_of_pfc116_in_air", "type": "standard_name", "name": "mole_fraction_of_pfc116_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for pfc116 is C2F6. The IUPAC name for pfc116 is hexafluoroethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_pfc218_in_air.json b/data_descriptors/standard_name/mole_fraction_of_pfc218_in_air.json index cc9d68b76..cbe417e4c 100644 --- a/data_descriptors/standard_name/mole_fraction_of_pfc218_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_pfc218_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_pfc218_in_air", + "id": "mole_fraction_of_pfc218_in_air", "type": "standard_name", "name": "mole_fraction_of_pfc218_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for pfc218 is C3F8. The IUPAC name for pfc218 is octafluoropropane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_pfc318_in_air.json b/data_descriptors/standard_name/mole_fraction_of_pfc318_in_air.json index fa7940873..ebda6db4f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_pfc318_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_pfc318_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_pfc318_in_air", + "id": "mole_fraction_of_pfc318_in_air", "type": "standard_name", "name": "mole_fraction_of_pfc318_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for pfc318 is c-C4F8. The IUPAC name for pfc318 is octafluorocyclobutane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_propane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_propane_in_air.json index 4abf761e7..fc7842ea1 100644 --- a/data_descriptors/standard_name/mole_fraction_of_propane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_propane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_propane_in_air", + "id": "mole_fraction_of_propane_in_air", "type": "standard_name", "name": "mole_fraction_of_propane_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_propene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_propene_in_air.json index 7099711f6..38cf02546 100644 --- a/data_descriptors/standard_name/mole_fraction_of_propene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_propene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_propene_in_air", + "id": "mole_fraction_of_propene_in_air", "type": "standard_name", "name": "mole_fraction_of_propene_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_radon_in_air.json b/data_descriptors/standard_name/mole_fraction_of_radon_in_air.json index c3e8cf375..4bab7c526 100644 --- a/data_descriptors/standard_name/mole_fraction_of_radon_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_radon_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_radon_in_air", + "id": "mole_fraction_of_radon_in_air", "type": "standard_name", "name": "mole_fraction_of_radon_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/mole_fraction_of_sulfur_dioxide_in_air.json b/data_descriptors/standard_name/mole_fraction_of_sulfur_dioxide_in_air.json index 04c654307..ad0afaa99 100644 --- a/data_descriptors/standard_name/mole_fraction_of_sulfur_dioxide_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_sulfur_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_sulfur_dioxide_in_air", + "id": "mole_fraction_of_sulfur_dioxide_in_air", "type": "standard_name", "name": "mole_fraction_of_sulfur_dioxide_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_fraction_of_sulfur_hexafluoride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_sulfur_hexafluoride_in_air.json index fff03058d..ec113cbd4 100644 --- a/data_descriptors/standard_name/mole_fraction_of_sulfur_hexafluoride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_sulfur_hexafluoride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_sulfur_hexafluoride_in_air", + "id": "mole_fraction_of_sulfur_hexafluoride_in_air", "type": "standard_name", "name": "mole_fraction_of_sulfur_hexafluoride_in_air", "description": "Mole fraction is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of sulfur hexafluoride is SF6.", diff --git a/data_descriptors/standard_name/mole_fraction_of_sulfuryl_fluoride_in_air.json b/data_descriptors/standard_name/mole_fraction_of_sulfuryl_fluoride_in_air.json index 86728e82c..4ceca47a0 100644 --- a/data_descriptors/standard_name/mole_fraction_of_sulfuryl_fluoride_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_sulfuryl_fluoride_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_sulfuryl_fluoride_in_air", + "id": "mole_fraction_of_sulfuryl_fluoride_in_air", "type": "standard_name", "name": "mole_fraction_of_sulfuryl_fluoride_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for sulfuryl fluoride is SO2F2. Sulfuryl fluoride is the IUPAC name.", diff --git a/data_descriptors/standard_name/mole_fraction_of_toluene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_toluene_in_air.json index 0e827eb1a..e69b1f16b 100644 --- a/data_descriptors/standard_name/mole_fraction_of_toluene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_toluene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_toluene_in_air", + "id": "mole_fraction_of_toluene_in_air", "type": "standard_name", "name": "mole_fraction_of_toluene_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/mole_fraction_of_tribromomethane_in_air.json b/data_descriptors/standard_name/mole_fraction_of_tribromomethane_in_air.json index 9a60047a7..c65e9550f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_tribromomethane_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_tribromomethane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_tribromomethane_in_air", + "id": "mole_fraction_of_tribromomethane_in_air", "type": "standard_name", "name": "mole_fraction_of_tribromomethane_in_air", "description": "\"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for tribromomethane is CHBr3. The IUPAC name is tribromomethane.", diff --git a/data_descriptors/standard_name/mole_fraction_of_water_vapor_in_air.json b/data_descriptors/standard_name/mole_fraction_of_water_vapor_in_air.json index 8b0241fe4..f7dc2cc02 100644 --- a/data_descriptors/standard_name/mole_fraction_of_water_vapor_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_water_vapor_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_water_vapor_in_air", + "id": "mole_fraction_of_water_vapor_in_air", "type": "standard_name", "name": "mole_fraction_of_water_vapor_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of water vapor is H2O.", diff --git a/data_descriptors/standard_name/mole_fraction_of_xylene_in_air.json b/data_descriptors/standard_name/mole_fraction_of_xylene_in_air.json index c7ebc0318..f7306207f 100644 --- a/data_descriptors/standard_name/mole_fraction_of_xylene_in_air.json +++ b/data_descriptors/standard_name/mole_fraction_of_xylene_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_fraction_of_xylene_in_air", + "id": "mole_fraction_of_xylene_in_air", "type": "standard_name", "name": "mole_fraction_of_xylene_in_air", "description": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/mole_ratio_of_nitrate_to_phosphate_in_sea_water.json b/data_descriptors/standard_name/mole_ratio_of_nitrate_to_phosphate_in_sea_water.json index fc88934af..d758d7806 100644 --- a/data_descriptors/standard_name/mole_ratio_of_nitrate_to_phosphate_in_sea_water.json +++ b/data_descriptors/standard_name/mole_ratio_of_nitrate_to_phosphate_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/mole_ratio_of_nitrate_to_phosphate_in_sea_water", + "id": "mole_ratio_of_nitrate_to_phosphate_in_sea_water", "type": "standard_name", "name": "mole_ratio_of_nitrate_to_phosphate_in_sea_water", "description": "\"Mole ratio\" is used in the construction \"mole_ratio_of_X_to_Y_in_medium\", where X and Y are both material constituents of the medium. \"Medium\" can take any of the values given in the \"medium\" section of the standard name Guidelines document. The phrase \"ratio_of_X_to_Y\" means X/Y. The chemical formula for the nitrate anion is NO3-. The chemical formula of the phosphate anion is PO4 with a charge of minus three.", diff --git a/data_descriptors/standard_name/moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water.json index e969a037a..2aaeadd91 100644 --- a/data_descriptors/standard_name/moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water", + "id": "moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_adenosine_triphosphate_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/ATPXZZDZ/2/.", diff --git a/data_descriptors/standard_name/moles_of_ammonium_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_ammonium_per_unit_mass_in_sea_water.json index 0829c489d..59f7ea951 100644 --- a/data_descriptors/standard_name/moles_of_ammonium_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_ammonium_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_ammonium_per_unit_mass_in_sea_water", + "id": "moles_of_ammonium_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_ammonium_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of ammonium is NH4. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/MDMAP004/3/.", diff --git a/data_descriptors/standard_name/moles_of_cfc11_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_cfc11_per_unit_mass_in_sea_water.json index 02171c508..9b41d8909 100644 --- a/data_descriptors/standard_name/moles_of_cfc11_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_cfc11_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_cfc11_per_unit_mass_in_sea_water", + "id": "moles_of_cfc11_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_cfc11_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water.json index 5b705f195..f5ca2cacc 100644 --- a/data_descriptors/standard_name/moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water", + "id": "moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_dissolved_inorganic_carbon_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water.json index 08d28750a..bc25a8ef2 100644 --- a/data_descriptors/standard_name/moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water", + "id": "moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_dissolved_nitrogen_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved nitrogen\" means the sum of all nitrogen in solution: inorganic nitrogen (nitrite, nitrate and ammonium) plus nitrogen in carbon compounds.", diff --git a/data_descriptors/standard_name/moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water.json index a2f598b18..154f492dd 100644 --- a/data_descriptors/standard_name/moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water", + "id": "moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_dissolved_organic_carbon_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/CORGZZKG/1/.", diff --git a/data_descriptors/standard_name/moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water.json index c5e041303..f93dc4568 100644 --- a/data_descriptors/standard_name/moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water", + "id": "moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_dissolved_organic_nitrogen_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Dissolved organic nitrogen\" describes the nitrogen held in carbon compounds in solution. These are mostly generated by plankton excretion and decay. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/MDMAP008/3/.", diff --git a/data_descriptors/standard_name/moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water.json index 03ca3ddab..119655f55 100644 --- a/data_descriptors/standard_name/moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water", + "id": "moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_dissolved_organic_phosphorus_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\u201d. \"Organic phosphorus\" means phosphorus in carbon compounds. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/ORGPMSZZ/4/.", diff --git a/data_descriptors/standard_name/moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water.json index 440370cfb..e6aa8d8c3 100644 --- a/data_descriptors/standard_name/moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water", + "id": "moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_dissolved_phosphorus_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \u201cPhosphorus\u201d means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at\nhttp://vocab.nerc.ac.uk/collection/P01/current/TPHSDSZZ/6/.", diff --git a/data_descriptors/standard_name/moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water.json index 2089919ff..a7d648206 100644 --- a/data_descriptors/standard_name/moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water", + "id": "moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_guanosine_triphosphate_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of guanosine triphosphate is C10H16N5O14P3.", diff --git a/data_descriptors/standard_name/moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water.json index 22dcb489d..98b91ccb5 100644 --- a/data_descriptors/standard_name/moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water", + "id": "moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_hydrogen_peroxide_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water.json index ecf95e81f..fc3366649 100644 --- a/data_descriptors/standard_name/moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water", + "id": "moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water", "description": "moles_of_X_per_unit_mass_inY is also called \"molality\" of X in Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/moles_of_nitrate_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_nitrate_per_unit_mass_in_sea_water.json index d7946696e..50b23d0ee 100644 --- a/data_descriptors/standard_name/moles_of_nitrate_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_nitrate_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_nitrate_per_unit_mass_in_sea_water", + "id": "moles_of_nitrate_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_nitrate_per_unit_mass_in_sea_water", "description": "moles_of_X_per_unit_mass_inY is also called \"molality\" of X in Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/moles_of_nitrite_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_nitrite_per_unit_mass_in_sea_water.json index 347ba9a84..8dd773ad1 100644 --- a/data_descriptors/standard_name/moles_of_nitrite_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_nitrite_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_nitrite_per_unit_mass_in_sea_water", + "id": "moles_of_nitrite_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_nitrite_per_unit_mass_in_sea_water", "description": "moles_of_X_per_unit_mass_inY is also called \"molality\" of X in Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/moles_of_nitrous_oxide_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_nitrous_oxide_per_unit_mass_in_sea_water.json index fb01922ed..20bb1906d 100644 --- a/data_descriptors/standard_name/moles_of_nitrous_oxide_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_nitrous_oxide_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_nitrous_oxide_per_unit_mass_in_sea_water", + "id": "moles_of_nitrous_oxide_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_nitrous_oxide_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrous oxide is N2O. The chemical formula for nitrous oxide is N2O. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/DN2OZZ01/.", diff --git a/data_descriptors/standard_name/moles_of_oxygen_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_oxygen_per_unit_mass_in_sea_water.json index 201d793b9..e37945b11 100644 --- a/data_descriptors/standard_name/moles_of_oxygen_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_oxygen_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_oxygen_per_unit_mass_in_sea_water", + "id": "moles_of_oxygen_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_oxygen_per_unit_mass_in_sea_water", "description": "moles_of_X_per_unit_mass_inY is also called \"molality\" of X in Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water.json index 49b01988c..23b761da2 100644 --- a/data_descriptors/standard_name/moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_biogenic_silica_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Particulate means suspended solids of all sizes. Biogenic silica is a hydrated form of silica (silicon dioxide) with the chemical formula SiO2.nH2O sometimes referred to as opaline silica or opal. It is created by biological processes and in sea water it is predominantly the skeletal material of diatoms.", diff --git a/data_descriptors/standard_name/moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water.json index bd660b400..d0ca9cae7 100644 --- a/data_descriptors/standard_name/moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_inorganic_carbon_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Particulate means suspended solids of all sizes. Particulate inorganic carbon is carbon bound in molecules ionically that may be liberated from the particles as carbon dioxide by acidification.", diff --git a/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json index b7d9a27f3..96e78ff02 100644 --- a/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_matter_expressed_as_carbon_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/MDMAP011/4/.", diff --git a/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json index 282727317..bc57297b5 100644 --- a/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/MDMAP013/4/.", diff --git a/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json index eeba43386..7d32aa612 100644 --- a/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes. Phosphorus means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/TPHSVLPT/5/.", diff --git a/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json index e2b1a32e1..37c7fd315 100644 --- a/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_organic_matter_expressed_as_carbon_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json index 99bf0fbae..6b5a7acad 100644 --- a/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_organic_matter_expressed_as_nitrogen_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json index 34de4631f..2fffaa36d 100644 --- a/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water", + "id": "moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_particulate_organic_matter_expressed_as_phosphorus_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Particulate means suspended solids of all sizes. Phosphorus means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\". The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/OPHSVLPT/6/.", diff --git a/data_descriptors/standard_name/moles_of_phosphate_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_phosphate_per_unit_mass_in_sea_water.json index b97342459..a8c62a728 100644 --- a/data_descriptors/standard_name/moles_of_phosphate_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_phosphate_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_phosphate_per_unit_mass_in_sea_water", + "id": "moles_of_phosphate_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_phosphate_per_unit_mass_in_sea_water", "description": "moles_of_X_per_unit_mass_inY is also called \"molality\" of X in Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/moles_of_silicate_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_silicate_per_unit_mass_in_sea_water.json index e2c49fb22..f11820811 100644 --- a/data_descriptors/standard_name/moles_of_silicate_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_silicate_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_silicate_per_unit_mass_in_sea_water", + "id": "moles_of_silicate_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_silicate_per_unit_mass_in_sea_water", "description": "moles_of_X_per_unit_mass_inY is also called \"molality\" of X in Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water.json b/data_descriptors/standard_name/moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water.json index 36ecb69a1..92bec5743 100644 --- a/data_descriptors/standard_name/moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water.json +++ b/data_descriptors/standard_name/moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water", + "id": "moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water", "type": "standard_name", "name": "moles_of_sulfur_hexafluoride_per_unit_mass_in_sea_water", "description": "The construction \"moles_of_X_per_unit_mass_in_Y\" is also called \"molality\" of X in Y, where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula of sulfur hexafluoride is SF6.", diff --git a/data_descriptors/standard_name/multi_variate_test_quality_flag.json b/data_descriptors/standard_name/multi_variate_test_quality_flag.json index a5d8f313e..dbe932c5b 100644 --- a/data_descriptors/standard_name/multi_variate_test_quality_flag.json +++ b/data_descriptors/standard_name/multi_variate_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/multi_variate_test_quality_flag", + "id": "multi_variate_test_quality_flag", "type": "standard_name", "name": "multi_variate_test_quality_flag", "description": "A quality flag that reports the result of the Multi-variate test, which checks that values are reasonable when compared with related variables. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/neighbor_test_quality_flag.json b/data_descriptors/standard_name/neighbor_test_quality_flag.json index fd8290147..f2dfc8dd6 100644 --- a/data_descriptors/standard_name/neighbor_test_quality_flag.json +++ b/data_descriptors/standard_name/neighbor_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/neighbor_test_quality_flag", + "id": "neighbor_test_quality_flag", "type": "standard_name", "name": "neighbor_test_quality_flag", "description": "A quality flag that reports the result of the Neighbor test, which checks that values are reasonable when compared with nearby measurements. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/net_downward_longwave_flux_in_air.json b/data_descriptors/standard_name/net_downward_longwave_flux_in_air.json index 619649fae..fb9829d1c 100644 --- a/data_descriptors/standard_name/net_downward_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/net_downward_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_downward_longwave_flux_in_air", + "id": "net_downward_longwave_flux_in_air", "type": "standard_name", "name": "net_downward_longwave_flux_in_air", "description": "\"longwave\" means longwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_downward_longwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/net_downward_longwave_flux_in_air_assuming_clear_sky.json index 9e6d24752..974a52beb 100644 --- a/data_descriptors/standard_name/net_downward_longwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/net_downward_longwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_downward_longwave_flux_in_air_assuming_clear_sky", + "id": "net_downward_longwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "net_downward_longwave_flux_in_air_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_downward_radiative_flux_at_top_of_atmosphere_model.json b/data_descriptors/standard_name/net_downward_radiative_flux_at_top_of_atmosphere_model.json index 8d4a0f722..31aba21ce 100644 --- a/data_descriptors/standard_name/net_downward_radiative_flux_at_top_of_atmosphere_model.json +++ b/data_descriptors/standard_name/net_downward_radiative_flux_at_top_of_atmosphere_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_downward_radiative_flux_at_top_of_atmosphere_model", + "id": "net_downward_radiative_flux_at_top_of_atmosphere_model", "type": "standard_name", "name": "net_downward_radiative_flux_at_top_of_atmosphere_model", "description": "Fluxes at the top_of_atmosphere_model differ from TOA fluxes only if the model TOA fluxes make some allowance for the atmosphere above the top of the model; if not, it is usual to give standard names with toa to the fluxes at the top of the model atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_downward_shortwave_flux_at_sea_water_surface.json b/data_descriptors/standard_name/net_downward_shortwave_flux_at_sea_water_surface.json index ddfbf71bf..e41c2efe3 100644 --- a/data_descriptors/standard_name/net_downward_shortwave_flux_at_sea_water_surface.json +++ b/data_descriptors/standard_name/net_downward_shortwave_flux_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_downward_shortwave_flux_at_sea_water_surface", + "id": "net_downward_shortwave_flux_at_sea_water_surface", "type": "standard_name", "name": "net_downward_shortwave_flux_at_sea_water_surface", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The term \"shortwave\" means shortwave radiation. The phrase \"sea water surface\" means the upper boundary of the liquid portion of an ocean or sea, including the boundary to floating ice if present.", diff --git a/data_descriptors/standard_name/net_downward_shortwave_flux_in_air.json b/data_descriptors/standard_name/net_downward_shortwave_flux_in_air.json index a283871b3..22df3735c 100644 --- a/data_descriptors/standard_name/net_downward_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/net_downward_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_downward_shortwave_flux_in_air", + "id": "net_downward_shortwave_flux_in_air", "type": "standard_name", "name": "net_downward_shortwave_flux_in_air", "description": "\"shortwave\" means shortwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_downward_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/net_downward_shortwave_flux_in_air_assuming_clear_sky.json index 8abc3f35a..5e0d9e90a 100644 --- a/data_descriptors/standard_name/net_downward_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/net_downward_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_downward_shortwave_flux_in_air_assuming_clear_sky", + "id": "net_downward_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "net_downward_shortwave_flux_in_air_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"shortwave\" means shortwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton.json index 137a66517..7f2590ec3 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Calcareous phytoplankton\" are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms.json index f0f35be1c..651b4d7e8 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Diatoms are single-celled phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton.json index 956504dfc..643a98702 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophic_phytoplankton", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton.json index c06be3896..c698017d6 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton.json index 0c99ba967..66873111e 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton.json index 86dcf3955..4e739a95c 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization.json b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization.json index 44b290e7c..d4f2a930a 100644 --- a/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization.json +++ b/data_descriptors/standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization", + "id": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization", "type": "standard_name", "name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization", "description": "\"Production of carbon\" refers to the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Nitrate utilization\" means net primary production by phytoplankton based on nitrate alone. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water.json b/data_descriptors/standard_name/net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water.json index 2d731f0ca..e63ca96f3 100644 --- a/data_descriptors/standard_name/net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water.json +++ b/data_descriptors/standard_name/net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water", + "id": "net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water", "type": "standard_name", "name": "net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water", "description": "Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon.json b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon.json index 0358a0fc2..70ff68cb5 100644 --- a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon.json +++ b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_productivity_of_biomass_expressed_as_carbon", + "id": "net_primary_productivity_of_biomass_expressed_as_carbon", "type": "standard_name", "name": "net_primary_productivity_of_biomass_expressed_as_carbon", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves.json b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves.json index 21b749d3c..9227d6c27 100644 --- a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves.json +++ b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves", + "id": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves", "type": "standard_name", "name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter.json b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter.json index f821c43d3..77ebd552f 100644 --- a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter.json +++ b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter", + "id": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter", "type": "standard_name", "name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter", "description": "\"Miscellaneous living matter\" means all those parts of plants that are not leaf, stem, root or other separately named components. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area.", diff --git a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots.json b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots.json index c4a6e61cb..0b64bedbf 100644 --- a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots.json +++ b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots", + "id": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots", "type": "standard_name", "name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems.json b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems.json index e9f41da4c..a16ec8808 100644 --- a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems.json +++ b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems", + "id": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems", "type": "standard_name", "name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The stem of a plant is the axis that bears buds and shoots with leaves and, at its basal end, roots. Its function is to carry water and nutrients. Examples include the stalk of a plant or the main trunk of a tree.", diff --git a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood.json b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood.json index 5bf35d684..52ac14424 100644 --- a/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood.json +++ b/data_descriptors/standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood", + "id": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood", "type": "standard_name", "name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood", "description": "\"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. \"Productivity\" means production per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer.json b/data_descriptors/standard_name/net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer.json index fcdf57a05..7e61a9225 100644 --- a/data_descriptors/standard_name/net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer", + "id": "net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer", "type": "standard_name", "name": "net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer", "description": "\"longwave\" means longwave radiation. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Net absorbed radiation is the difference between absorbed and emitted radiation.", diff --git a/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer.json b/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer.json index f6c746c03..91011b326 100644 --- a/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer", + "id": "net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer", "type": "standard_name", "name": "net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer", "description": "\"shortwave\" means shortwave radiation. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Net absorbed radiation is the difference between absorbed and emitted radiation.", diff --git a/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_ocean_layer.json b/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_ocean_layer.json index 2d47ac814..03258e92a 100644 --- a/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_ocean_layer.json +++ b/data_descriptors/standard_name/net_rate_of_absorption_of_shortwave_energy_in_ocean_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_rate_of_absorption_of_shortwave_energy_in_ocean_layer", + "id": "net_rate_of_absorption_of_shortwave_energy_in_ocean_layer", "type": "standard_name", "name": "net_rate_of_absorption_of_shortwave_energy_in_ocean_layer", "description": "\"shortwave\" means shortwave radiation. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Net absorbed radiation is the difference between absorbed and emitted radiation.", diff --git a/data_descriptors/standard_name/net_upward_longwave_flux_in_air.json b/data_descriptors/standard_name/net_upward_longwave_flux_in_air.json index 965340da8..0efe35bd4 100644 --- a/data_descriptors/standard_name/net_upward_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/net_upward_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_upward_longwave_flux_in_air", + "id": "net_upward_longwave_flux_in_air", "type": "standard_name", "name": "net_upward_longwave_flux_in_air", "description": "\"longwave\" means longwave radiation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_upward_longwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/net_upward_longwave_flux_in_air_assuming_clear_sky.json index 4896a373a..ce6300a6e 100644 --- a/data_descriptors/standard_name/net_upward_longwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/net_upward_longwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_upward_longwave_flux_in_air_assuming_clear_sky", + "id": "net_upward_longwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "net_upward_longwave_flux_in_air_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_upward_shortwave_flux_in_air.json b/data_descriptors/standard_name/net_upward_shortwave_flux_in_air.json index 6324030f4..bee38a634 100644 --- a/data_descriptors/standard_name/net_upward_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/net_upward_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_upward_shortwave_flux_in_air", + "id": "net_upward_shortwave_flux_in_air", "type": "standard_name", "name": "net_upward_shortwave_flux_in_air", "description": "\"shortwave\" means shortwave radiation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/net_upward_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/net_upward_shortwave_flux_in_air_assuming_clear_sky.json index bb6e1b9cb..e9a7c193a 100644 --- a/data_descriptors/standard_name/net_upward_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/net_upward_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/net_upward_shortwave_flux_in_air_assuming_clear_sky", + "id": "net_upward_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "net_upward_shortwave_flux_in_air_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"shortwave\" means shortwave radiation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/nfdrs_1000_hour_fuel_moisture.json b/data_descriptors/standard_name/nfdrs_1000_hour_fuel_moisture.json index 6448ee4ee..922ca7fd4 100644 --- a/data_descriptors/standard_name/nfdrs_1000_hour_fuel_moisture.json +++ b/data_descriptors/standard_name/nfdrs_1000_hour_fuel_moisture.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_1000_hour_fuel_moisture", + "id": "nfdrs_1000_hour_fuel_moisture", "type": "standard_name", "name": "nfdrs_1000_hour_fuel_moisture", "description": "1000 hour fuel moisture (FM1000) represents the modelled moisture content in the dead fuels in the 3 to 8 inch diameter class and the layer of the forest floor about 4 inches below the surface. The value is based on a running 7-day average. The 1000-hour time lag fuel moisture is a function of length of day (as influenced by latitude and calendar date), daily temperature and relative humidity extremes (maximum and minimum values) and the 24-hour precipitation duration values for a 7-day period. It is a component in the US National Fire Danger Rating System. The US National Fire Danger Rating System comprises several numeric indexes that rate the potential over a large area for wildland fires to ignite, spread, and require action to suppress or manage. It was designed for use in the continental United States, and all its components are relative, not absolute.", diff --git a/data_descriptors/standard_name/nfdrs_100_hour_fuel_moisture.json b/data_descriptors/standard_name/nfdrs_100_hour_fuel_moisture.json index c6f518dc4..d33f19d20 100644 --- a/data_descriptors/standard_name/nfdrs_100_hour_fuel_moisture.json +++ b/data_descriptors/standard_name/nfdrs_100_hour_fuel_moisture.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_100_hour_fuel_moisture", + "id": "nfdrs_100_hour_fuel_moisture", "type": "standard_name", "name": "nfdrs_100_hour_fuel_moisture", "description": "100 hour fuel moisture (FM100) represents the modeled moisture content of dead fuels in the 1 to 3 inch diameter class. It can also be used as a very rough estimate of the average moisture content of the forest floor from three-fourths inch to 4 inches below the surface. The 100-hour timelag fuel moisture is a function of length of day (as influenced by latitude and calendar date), maximum and minimum temperature and relative humidity, and precipitation duration in the previous 24 hours. It is a component in the US National Fire Danger Rating System. The US National Fire Danger Rating System comprises several numeric indexes that rate the potential over a large area for wildland fires to ignite, spread, and require action to suppress or manage. It was designed for use in the continental United States, and all its components are relative, not absolute.", diff --git a/data_descriptors/standard_name/nfdrs_10_hour_fuel_moisture.json b/data_descriptors/standard_name/nfdrs_10_hour_fuel_moisture.json index 54ae94cfe..5529ab50f 100644 --- a/data_descriptors/standard_name/nfdrs_10_hour_fuel_moisture.json +++ b/data_descriptors/standard_name/nfdrs_10_hour_fuel_moisture.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_10_hour_fuel_moisture", + "id": "nfdrs_10_hour_fuel_moisture", "type": "standard_name", "name": "nfdrs_10_hour_fuel_moisture", "description": "10 hour fuel moisture (FM10) represents the modeled moisture content of dead fuels consisting of roundwood in the size range of one quarter to 1 inch in diameter and very roughly, the layer of litter extending from just below the surface to three-quarters of inch below the surface. The 10-hour timelag fuel moisture is a function of length of day (as influenced by latitude and calendar date), daily downwelling shortwave radiation, daily maximum temperature and minimum relative humidity, and daily precipitation values. It is a component in the US National Fire Danger Rating System (cf. https://www.bia.gov/sites/default/files/dup/assets/public/pdf/idc-020513.pdf). The US National Fire Danger Rating System comprises several numeric indexes that rate the potential over a large area for wildland fires to ignite, spread, and require action to suppress or manage. It was designed for use in the continental United States, and all its components are relative, not absolute.", diff --git a/data_descriptors/standard_name/nfdrs_1_hour_fuel_moisture.json b/data_descriptors/standard_name/nfdrs_1_hour_fuel_moisture.json index 13dff46d5..603056ff0 100644 --- a/data_descriptors/standard_name/nfdrs_1_hour_fuel_moisture.json +++ b/data_descriptors/standard_name/nfdrs_1_hour_fuel_moisture.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_1_hour_fuel_moisture", + "id": "nfdrs_1_hour_fuel_moisture", "type": "standard_name", "name": "nfdrs_1_hour_fuel_moisture", "description": "1 hour fuel moisture (FM1) represents the modeled moisture content of dead fuels consisting of herbaceous plants or roundwood less than one-quarter inch in diameter. It also includes the uppermost layer of litter on the forest floor. The 1-hour timelag fuel moisture is a function of length of day (as influenced by latitude and calendar date), daily downwelling shortwave radiation, daily maximum temperature and minimum relative humidity, and daily precipitation values. It is a component in the US National Fire Danger Rating System (cf. https://www.bia.gov/sites/default/files/dup/assets/public/pdf/idc-020513.pdf). The US National Fire Danger Rating System comprises several numeric indexes that rate the potential over a large area for wildland fires to ignite, spread, and require action to suppress or manage. It was designed for use in the continental United States, and all its components are relative, not absolute .", diff --git a/data_descriptors/standard_name/nfdrs_burning_index.json b/data_descriptors/standard_name/nfdrs_burning_index.json index efd75a474..280109182 100644 --- a/data_descriptors/standard_name/nfdrs_burning_index.json +++ b/data_descriptors/standard_name/nfdrs_burning_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_burning_index", + "id": "nfdrs_burning_index", "type": "standard_name", "name": "nfdrs_burning_index", "description": "The Burning Index (BI) is a numeric value closely related to the flame length in feet multiplied by 10, which is related to the contribution of fire behaviour to the effort of containing a fire. The BI is a function of fire spread and fire intensity and is derived from a combination of Spread and Energy Release Components. The Spread Component is a rating of the forward rate of spread of a head fire and wind is a key input. The scale is open ended which allows the range of numbers to adequately define fire problems, even in time of low to moderate fire danger. Computed BI values represent the near upper limit to be expected on the rating area. In other words, if a fire occurs in the worst fuel, weather and topography conditions of the rating area, these numbers indicate its expected fire line intensities and flame length. It is an index in the US National Fire Danger Rating System. The US National Fire Danger Rating System comprises several numeric indexes that rate the potential over a large area for wildland fires to ignite, spread, and require action to suppress or manage. It was designed for use in the continental United States, and all its components are relative, not absolute.", diff --git a/data_descriptors/standard_name/nfdrs_energy_release_component.json b/data_descriptors/standard_name/nfdrs_energy_release_component.json index 8f21694bd..a031f494e 100644 --- a/data_descriptors/standard_name/nfdrs_energy_release_component.json +++ b/data_descriptors/standard_name/nfdrs_energy_release_component.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_energy_release_component", + "id": "nfdrs_energy_release_component", "type": "standard_name", "name": "nfdrs_energy_release_component", "description": "The Energy Release Component (ERC) is a number related to the available energy per unit area within the flaming front at the head of a fire. It is usually given in BTU ft-2. Daily variations in ERC are due to changes in moisture content of the various fuels present, both live and dead. It may also be considered a composite fuel moisture value as it reflects the contribution that all live and dead fuels have to potential fire intensity. Energy Release Component is a cumulative index. The scale is open-ended and relative. Energy Release Component values depend on the fuel model input into the calculations and interpretation of precise values varies with ecology and region. It is an index in the US National Fire Danger Rating System. The US National Fire Danger Rating System comprises several numeric indexes that rate the potential over a large area for wildland fires to ignite, spread, and require action to suppress or manage. It was designed for use in the continental United States, and all its components are relative, not absolute.", diff --git a/data_descriptors/standard_name/nfdrs_severe_fire_danger_index.json b/data_descriptors/standard_name/nfdrs_severe_fire_danger_index.json index 5276f24b5..b365bc9f0 100644 --- a/data_descriptors/standard_name/nfdrs_severe_fire_danger_index.json +++ b/data_descriptors/standard_name/nfdrs_severe_fire_danger_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nfdrs_severe_fire_danger_index", + "id": "nfdrs_severe_fire_danger_index", "type": "standard_name", "name": "nfdrs_severe_fire_danger_index", "description": "Severe Fire Danger Index (SFDI) is the normalized product of normalized Energy Release Component (ERC) and normalized Burning Index (BI) from the United States National Fire Danger Rating System (NFDRS). While SFDI is not officially part of the National Fire Danger Rating System, it is related to and intended to supplement NFDRS. It is commonly categorized into five classes based on percentile: low (0-60), moderate (60-80), high (80-90), very high (90-97), and extreme (97-100). It can be extended to future conditions by introducing an unprecedented category for values above the historical 100th percentile. As it is locally normalized, its interpretation remains the same across space.", diff --git a/data_descriptors/standard_name/nitrogen_growth_limitation_of_calcareous_phytoplankton.json b/data_descriptors/standard_name/nitrogen_growth_limitation_of_calcareous_phytoplankton.json index 9e29f2ab4..0da7198b4 100644 --- a/data_descriptors/standard_name/nitrogen_growth_limitation_of_calcareous_phytoplankton.json +++ b/data_descriptors/standard_name/nitrogen_growth_limitation_of_calcareous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_growth_limitation_of_calcareous_phytoplankton", + "id": "nitrogen_growth_limitation_of_calcareous_phytoplankton", "type": "standard_name", "name": "nitrogen_growth_limitation_of_calcareous_phytoplankton", "description": "\"Calcareous phytoplankton\" are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Nitrogen growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", diff --git a/data_descriptors/standard_name/nitrogen_growth_limitation_of_diatoms.json b/data_descriptors/standard_name/nitrogen_growth_limitation_of_diatoms.json index b85192caf..4d3700d87 100644 --- a/data_descriptors/standard_name/nitrogen_growth_limitation_of_diatoms.json +++ b/data_descriptors/standard_name/nitrogen_growth_limitation_of_diatoms.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_growth_limitation_of_diatoms", + "id": "nitrogen_growth_limitation_of_diatoms", "type": "standard_name", "name": "nitrogen_growth_limitation_of_diatoms", "description": "Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Nitrogen growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", diff --git a/data_descriptors/standard_name/nitrogen_growth_limitation_of_diazotrophic_phytoplankton.json b/data_descriptors/standard_name/nitrogen_growth_limitation_of_diazotrophic_phytoplankton.json index 7932c319c..0b0ce509f 100644 --- a/data_descriptors/standard_name/nitrogen_growth_limitation_of_diazotrophic_phytoplankton.json +++ b/data_descriptors/standard_name/nitrogen_growth_limitation_of_diazotrophic_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_growth_limitation_of_diazotrophic_phytoplankton", + "id": "nitrogen_growth_limitation_of_diazotrophic_phytoplankton", "type": "standard_name", "name": "nitrogen_growth_limitation_of_diazotrophic_phytoplankton", "description": "\"Nitrogen growth limitation\" means the ratio of the growth rate of a biological population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/nitrogen_growth_limitation_of_miscellaneous_phytoplankton.json b/data_descriptors/standard_name/nitrogen_growth_limitation_of_miscellaneous_phytoplankton.json index dd6510c89..c16dc5e1c 100644 --- a/data_descriptors/standard_name/nitrogen_growth_limitation_of_miscellaneous_phytoplankton.json +++ b/data_descriptors/standard_name/nitrogen_growth_limitation_of_miscellaneous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_growth_limitation_of_miscellaneous_phytoplankton", + "id": "nitrogen_growth_limitation_of_miscellaneous_phytoplankton", "type": "standard_name", "name": "nitrogen_growth_limitation_of_miscellaneous_phytoplankton", "description": "Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. \"Nitrogen growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", diff --git a/data_descriptors/standard_name/nitrogen_growth_limitation_of_picophytoplankton.json b/data_descriptors/standard_name/nitrogen_growth_limitation_of_picophytoplankton.json index 326e8fe87..8c3be26df 100644 --- a/data_descriptors/standard_name/nitrogen_growth_limitation_of_picophytoplankton.json +++ b/data_descriptors/standard_name/nitrogen_growth_limitation_of_picophytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_growth_limitation_of_picophytoplankton", + "id": "nitrogen_growth_limitation_of_picophytoplankton", "type": "standard_name", "name": "nitrogen_growth_limitation_of_picophytoplankton", "description": "Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Nitrogen growth limitation\" means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", diff --git a/data_descriptors/standard_name/nitrogen_mass_content_of_forestry_and_agricultural_products.json b/data_descriptors/standard_name/nitrogen_mass_content_of_forestry_and_agricultural_products.json index 6fd92c5a7..f041f9676 100644 --- a/data_descriptors/standard_name/nitrogen_mass_content_of_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/nitrogen_mass_content_of_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_mass_content_of_forestry_and_agricultural_products", + "id": "nitrogen_mass_content_of_forestry_and_agricultural_products", "type": "standard_name", "name": "nitrogen_mass_content_of_forestry_and_agricultural_products", "description": "\"Content\" indicates a quantity per unit area. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites.", diff --git a/data_descriptors/standard_name/nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json b/data_descriptors/standard_name/nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json index 32fd849e3..3dc545bf5 100644 --- a/data_descriptors/standard_name/nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json +++ b/data_descriptors/standard_name/nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", + "id": "nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "type": "standard_name", "name": "nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of nitrogen that represent these products in order to conserve nitrogen and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites. \"Anthropogenic\" means influenced, caused, or created by human activity. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/nitrogen_mass_flux_into_litter_from_vegetation.json b/data_descriptors/standard_name/nitrogen_mass_flux_into_litter_from_vegetation.json index 63fdaeafc..e589ab85e 100644 --- a/data_descriptors/standard_name/nitrogen_mass_flux_into_litter_from_vegetation.json +++ b/data_descriptors/standard_name/nitrogen_mass_flux_into_litter_from_vegetation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_mass_flux_into_litter_from_vegetation", + "id": "nitrogen_mass_flux_into_litter_from_vegetation", "type": "standard_name", "name": "nitrogen_mass_flux_into_litter_from_vegetation", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Litter\" is dead plant material in or above the soil. \"Vegetation\" means any living plants e.g. trees, shrubs, grass.", diff --git a/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_litter.json b/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_litter.json index 8dc97204a..db78963f6 100644 --- a/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_litter.json +++ b/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_litter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_mass_flux_into_soil_from_litter", + "id": "nitrogen_mass_flux_into_soil_from_litter", "type": "standard_name", "name": "nitrogen_mass_flux_into_soil_from_litter", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Litter\" is dead plant material in or above the soil.", diff --git a/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter.json b/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter.json index 589474182..a387546fd 100644 --- a/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter.json +++ b/data_descriptors/standard_name/nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter", + "id": "nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter", "type": "standard_name", "name": "nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil.", diff --git a/data_descriptors/standard_name/nitrogen_mass_transport_in_river_channel.json b/data_descriptors/standard_name/nitrogen_mass_transport_in_river_channel.json index ee3bfd6a5..eb126756b 100644 --- a/data_descriptors/standard_name/nitrogen_mass_transport_in_river_channel.json +++ b/data_descriptors/standard_name/nitrogen_mass_transport_in_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nitrogen_mass_transport_in_river_channel", + "id": "nitrogen_mass_transport_in_river_channel", "type": "standard_name", "name": "nitrogen_mass_transport_in_river_channel", "description": "The amount of total nitrogen mass transported in the river channels from land into the ocean. This quantity can be provided at a certain location within the river network and floodplain (over land) or at the river mouth (over ocean) where the river enters the ocean. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/non_tidal_elevation_of_sea_surface_height.json b/data_descriptors/standard_name/non_tidal_elevation_of_sea_surface_height.json index aa382acc5..144926812 100644 --- a/data_descriptors/standard_name/non_tidal_elevation_of_sea_surface_height.json +++ b/data_descriptors/standard_name/non_tidal_elevation_of_sea_surface_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/non_tidal_elevation_of_sea_surface_height", + "id": "non_tidal_elevation_of_sea_surface_height", "type": "standard_name", "name": "non_tidal_elevation_of_sea_surface_height", "description": "\"Sea surface height\" is a time-varying quantity. The phrase \"non_tidal_elevation\" describes the contribution to sea surface height variability made by processes other than astronomic forcing of the ocean and shallow water resonance of tidal components. These processes include storm surge (due to a combination of meteorological forcing of the ocean and interaction between the generated surge and tides), effects of surface ocean waves, and seasonal and climatic variation in ocean density and circulation. The contribution made by each process varies according to the averaging time of the variable as described by the bounds and cell_methods attributes of the data variable.", diff --git a/data_descriptors/standard_name/normalized_difference_vegetation_index.json b/data_descriptors/standard_name/normalized_difference_vegetation_index.json index aec7aed52..4121e2d67 100644 --- a/data_descriptors/standard_name/normalized_difference_vegetation_index.json +++ b/data_descriptors/standard_name/normalized_difference_vegetation_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/normalized_difference_vegetation_index", + "id": "normalized_difference_vegetation_index", "type": "standard_name", "name": "normalized_difference_vegetation_index", "description": "\"Normalized_difference_vegetation_index\", usually abbreviated to NDVI, is an index calculated from reflectances measured in the visible and near infrared channels. It is calculated as NDVI = (NIR - R) / (NIR + R) where NIR is the reflectance in the near-infrared band and R is the reflectance in the red visible band. Reflectance is the ratio of the reflected over the incoming radiation in each spectral band. The calculated value of NDVI depends on the precise definitions of the spectral bands and these definitions may vary between different models and remote sensing instruments.", diff --git a/data_descriptors/standard_name/northward_air_velocity_relative_to_sea_water.json b/data_descriptors/standard_name/northward_air_velocity_relative_to_sea_water.json index c37f3a424..c1c7ede0b 100644 --- a/data_descriptors/standard_name/northward_air_velocity_relative_to_sea_water.json +++ b/data_descriptors/standard_name/northward_air_velocity_relative_to_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_air_velocity_relative_to_sea_water", + "id": "northward_air_velocity_relative_to_sea_water", "type": "standard_name", "name": "northward_air_velocity_relative_to_sea_water", "description": "The northward motion of air, relative to near-surface northward current; calculated as northward_wind minus northward_sea_water_velocity. A vertical coordinate variable or scalar coordinate with standard name \"depth\" should be used to indicate the depth of sea water velocity used in the calculation. Similarly, a vertical coordinate variable or scalar coordinate with standard name \"height\" should be used to indicate the height of the the wind component. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward).", diff --git a/data_descriptors/standard_name/northward_atmosphere_dry_static_energy_transport_across_unit_distance.json b/data_descriptors/standard_name/northward_atmosphere_dry_static_energy_transport_across_unit_distance.json index 7c41631ce..d009e6a0e 100644 --- a/data_descriptors/standard_name/northward_atmosphere_dry_static_energy_transport_across_unit_distance.json +++ b/data_descriptors/standard_name/northward_atmosphere_dry_static_energy_transport_across_unit_distance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_atmosphere_dry_static_energy_transport_across_unit_distance", + "id": "northward_atmosphere_dry_static_energy_transport_across_unit_distance", "type": "standard_name", "name": "northward_atmosphere_dry_static_energy_transport_across_unit_distance", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/northward_atmosphere_heat_transport.json b/data_descriptors/standard_name/northward_atmosphere_heat_transport.json index 55cdc9eb7..b7c704906 100644 --- a/data_descriptors/standard_name/northward_atmosphere_heat_transport.json +++ b/data_descriptors/standard_name/northward_atmosphere_heat_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_atmosphere_heat_transport", + "id": "northward_atmosphere_heat_transport", "type": "standard_name", "name": "northward_atmosphere_heat_transport", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Atmosphere heat transport\" means total heat transport by the atmosphere by all processes.", diff --git a/data_descriptors/standard_name/northward_atmosphere_water_transport_across_unit_distance.json b/data_descriptors/standard_name/northward_atmosphere_water_transport_across_unit_distance.json index b6fe9ec67..3549c3d30 100644 --- a/data_descriptors/standard_name/northward_atmosphere_water_transport_across_unit_distance.json +++ b/data_descriptors/standard_name/northward_atmosphere_water_transport_across_unit_distance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_atmosphere_water_transport_across_unit_distance", + "id": "northward_atmosphere_water_transport_across_unit_distance", "type": "standard_name", "name": "northward_atmosphere_water_transport_across_unit_distance", "description": "\"Water\" means water in all phases. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.", diff --git a/data_descriptors/standard_name/northward_atmosphere_water_vapor_transport_across_unit_distance.json b/data_descriptors/standard_name/northward_atmosphere_water_vapor_transport_across_unit_distance.json index 5d78d027e..706be48b7 100644 --- a/data_descriptors/standard_name/northward_atmosphere_water_vapor_transport_across_unit_distance.json +++ b/data_descriptors/standard_name/northward_atmosphere_water_vapor_transport_across_unit_distance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_atmosphere_water_vapor_transport_across_unit_distance", + "id": "northward_atmosphere_water_vapor_transport_across_unit_distance", "type": "standard_name", "name": "northward_atmosphere_water_vapor_transport_across_unit_distance", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.", diff --git a/data_descriptors/standard_name/northward_derivative_of_eastward_sea_ice_velocity.json b/data_descriptors/standard_name/northward_derivative_of_eastward_sea_ice_velocity.json index b8b56c8f6..68bdf205a 100644 --- a/data_descriptors/standard_name/northward_derivative_of_eastward_sea_ice_velocity.json +++ b/data_descriptors/standard_name/northward_derivative_of_eastward_sea_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_derivative_of_eastward_sea_ice_velocity", + "id": "northward_derivative_of_eastward_sea_ice_velocity", "type": "standard_name", "name": "northward_derivative_of_eastward_sea_ice_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Sea ice velocity is defined as a two-dimensional vector, with no vertical component. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. The named quantity is a component of the strain rate tensor for sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/northward_derivative_of_eastward_wind.json b/data_descriptors/standard_name/northward_derivative_of_eastward_wind.json index 81c526fb5..ff5ef4b7a 100644 --- a/data_descriptors/standard_name/northward_derivative_of_eastward_wind.json +++ b/data_descriptors/standard_name/northward_derivative_of_eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_derivative_of_eastward_wind", + "id": "northward_derivative_of_eastward_wind", "type": "standard_name", "name": "northward_derivative_of_eastward_wind", "description": "The quantity with standard name northward_derivative_of_eastward_wind is the derivative of the eastward component of the wind with respect to distance in the northward direction for a given atmospheric level. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/northward_derivative_of_northward_wind.json b/data_descriptors/standard_name/northward_derivative_of_northward_wind.json index cecfad6d6..8dc0dd700 100644 --- a/data_descriptors/standard_name/northward_derivative_of_northward_wind.json +++ b/data_descriptors/standard_name/northward_derivative_of_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_derivative_of_northward_wind", + "id": "northward_derivative_of_northward_wind", "type": "standard_name", "name": "northward_derivative_of_northward_wind", "description": "The quantity with standard name northward_derivative_of_northward_wind is the derivative of the northward component of wind with respect to distance in the northward direction for a given atmospheric level. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/northward_derivative_of_wind_from_direction.json b/data_descriptors/standard_name/northward_derivative_of_wind_from_direction.json index 4850335b0..ca3bc8060 100644 --- a/data_descriptors/standard_name/northward_derivative_of_wind_from_direction.json +++ b/data_descriptors/standard_name/northward_derivative_of_wind_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_derivative_of_wind_from_direction", + "id": "northward_derivative_of_wind_from_direction", "type": "standard_name", "name": "northward_derivative_of_wind_from_direction", "description": "The quantity with standard name northward_derivative_of_wind_from_direction is the derivative of wind from_direction with respect to the change in northward lateral position for a given atmospheric level. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (\"wind_from_direction\") (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (\"wind_to_direction\") (eastward, southward, etc.). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/northward_eliassen_palm_flux_in_air.json b/data_descriptors/standard_name/northward_eliassen_palm_flux_in_air.json index d0a5d576d..fa7073845 100644 --- a/data_descriptors/standard_name/northward_eliassen_palm_flux_in_air.json +++ b/data_descriptors/standard_name/northward_eliassen_palm_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_eliassen_palm_flux_in_air", + "id": "northward_eliassen_palm_flux_in_air", "type": "standard_name", "name": "northward_eliassen_palm_flux_in_air", "description": "\"Eliassen Palm flux\" is a widely used vector in the meridional plane, and the divergence of this flux appears as a forcing in the Transformed Eulerian mean formulation of the zonal mean zonal wind equation. \"Northward\" indicates a vector component which is positive when directed northward (negative southward).", diff --git a/data_descriptors/standard_name/northward_flood_water_velocity.json b/data_descriptors/standard_name/northward_flood_water_velocity.json index 96675ac74..8613c4d53 100644 --- a/data_descriptors/standard_name/northward_flood_water_velocity.json +++ b/data_descriptors/standard_name/northward_flood_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_flood_water_velocity", + "id": "northward_flood_water_velocity", "type": "standard_name", "name": "northward_flood_water_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/northward_friction_velocity_at_sea_water_surface.json b/data_descriptors/standard_name/northward_friction_velocity_at_sea_water_surface.json index 35fd9d966..5d5bcd114 100644 --- a/data_descriptors/standard_name/northward_friction_velocity_at_sea_water_surface.json +++ b/data_descriptors/standard_name/northward_friction_velocity_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_friction_velocity_at_sea_water_surface", + "id": "northward_friction_velocity_at_sea_water_surface", "type": "standard_name", "name": "northward_friction_velocity_at_sea_water_surface", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Friction velocity is a reference ocean velocity derived from the relationship between ocean density and downward stress and is usually applied at a level close to the surface where stress is assumed to be independent of height and approximately proportional to the square of mean velocity.", diff --git a/data_descriptors/standard_name/northward_friction_velocity_in_air.json b/data_descriptors/standard_name/northward_friction_velocity_in_air.json index c99781d59..36822744a 100644 --- a/data_descriptors/standard_name/northward_friction_velocity_in_air.json +++ b/data_descriptors/standard_name/northward_friction_velocity_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_friction_velocity_in_air", + "id": "northward_friction_velocity_in_air", "type": "standard_name", "name": "northward_friction_velocity_in_air", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Friction velocity is a reference wind velocity derived from the relationship between air density and downward stress and is usually applied at a level close to the surface where stress is assumed to independent of height and approximately proportional to the square of mean velocity.", diff --git a/data_descriptors/standard_name/northward_heat_flux_in_air_due_to_eddy_advection.json b/data_descriptors/standard_name/northward_heat_flux_in_air_due_to_eddy_advection.json index 9c37bb47e..7ace2153a 100644 --- a/data_descriptors/standard_name/northward_heat_flux_in_air_due_to_eddy_advection.json +++ b/data_descriptors/standard_name/northward_heat_flux_in_air_due_to_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_heat_flux_in_air_due_to_eddy_advection", + "id": "northward_heat_flux_in_air_due_to_eddy_advection", "type": "standard_name", "name": "northward_heat_flux_in_air_due_to_eddy_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/northward_land_ice_velocity.json b/data_descriptors/standard_name/northward_land_ice_velocity.json index b03f1e02f..cfc3595c7 100644 --- a/data_descriptors/standard_name/northward_land_ice_velocity.json +++ b/data_descriptors/standard_name/northward_land_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_land_ice_velocity", + "id": "northward_land_ice_velocity", "type": "standard_name", "name": "northward_land_ice_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Land ice velocity is defined as a two-dimensional vector, with no vertical component. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves.", diff --git a/data_descriptors/standard_name/northward_mass_flux_of_air.json b/data_descriptors/standard_name/northward_mass_flux_of_air.json index 56d4da826..b3091a35a 100644 --- a/data_descriptors/standard_name/northward_mass_flux_of_air.json +++ b/data_descriptors/standard_name/northward_mass_flux_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_mass_flux_of_air", + "id": "northward_mass_flux_of_air", "type": "standard_name", "name": "northward_mass_flux_of_air", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/northward_momentum_flux_correction.json b/data_descriptors/standard_name/northward_momentum_flux_correction.json index 8393f6d0f..456a8ecf5 100644 --- a/data_descriptors/standard_name/northward_momentum_flux_correction.json +++ b/data_descriptors/standard_name/northward_momentum_flux_correction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_momentum_flux_correction", + "id": "northward_momentum_flux_correction", "type": "standard_name", "name": "northward_momentum_flux_correction", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. Flux correction is also called \"flux adjustment\". A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/northward_northward_derivative_of_geopotential.json b/data_descriptors/standard_name/northward_northward_derivative_of_geopotential.json index 1263498c9..0db76d025 100644 --- a/data_descriptors/standard_name/northward_northward_derivative_of_geopotential.json +++ b/data_descriptors/standard_name/northward_northward_derivative_of_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_northward_derivative_of_geopotential", + "id": "northward_northward_derivative_of_geopotential", "type": "standard_name", "name": "northward_northward_derivative_of_geopotential", "description": "A quantity with standard name Xward_Yward_derivative_of_geopotential is a second spatial derivative of geopotential, P, in the direction specified by X and Y, i.e., d2P/dXdY. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude.", diff --git a/data_descriptors/standard_name/northward_ocean_freshwater_transport.json b/data_descriptors/standard_name/northward_ocean_freshwater_transport.json index 2163fb1ed..b902af0f6 100644 --- a/data_descriptors/standard_name/northward_ocean_freshwater_transport.json +++ b/data_descriptors/standard_name/northward_ocean_freshwater_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_freshwater_transport", + "id": "northward_ocean_freshwater_transport", "type": "standard_name", "name": "northward_ocean_freshwater_transport", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Ocean transport means transport by all processes, both sea water and sea ice.", diff --git a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_diffusion.json b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_diffusion.json index b091e1a91..bb57e9875 100644 --- a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_diffusion.json +++ b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_freshwater_transport_due_to_diffusion", + "id": "northward_ocean_freshwater_transport_due_to_diffusion", "type": "standard_name", "name": "northward_ocean_freshwater_transport_due_to_diffusion", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Northward transport by diffusion means the part due to horizontal or isopyncal diffusion schemes in an ocean model, but not including the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_gyre.json b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_gyre.json index d16dd41eb..dd383ad94 100644 --- a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_gyre.json +++ b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_gyre.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_freshwater_transport_due_to_gyre", + "id": "northward_ocean_freshwater_transport_due_to_gyre", "type": "standard_name", "name": "northward_ocean_freshwater_transport_due_to_gyre", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Northward transport by the ocean gyre is geometrically defined as being the part due to the vertical integral of the product of deviations of velocity and tracer from their zonal means. The velocity does not include the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_overturning.json b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_overturning.json index 28659a097..08e9e9058 100644 --- a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_overturning.json +++ b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_overturning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_freshwater_transport_due_to_overturning", + "id": "northward_ocean_freshwater_transport_due_to_overturning", "type": "standard_name", "name": "northward_ocean_freshwater_transport_due_to_overturning", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Northward transport by (meridional) overturning is geometrically defined as being the part due to the vertical integral of the product of zonal means of velocity and tracer. The velocity does not include the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection.json index da742b17e..bb5022560 100644 --- a/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection", + "id": "northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "northward_ocean_freshwater_transport_due_to_parameterized_eddy_advection", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport.json b/data_descriptors/standard_name/northward_ocean_heat_transport.json index 370fcf3d2..d49dda40e 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport", + "id": "northward_ocean_heat_transport", "type": "standard_name", "name": "northward_ocean_heat_transport", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Ocean transport means transport by all processes, both sea water and sea ice.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_diffusion.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_diffusion.json index befeed2dc..602f85968 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_diffusion.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_diffusion", + "id": "northward_ocean_heat_transport_due_to_diffusion", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_diffusion", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Northward transport by diffusion means the part due to horizontal or isopyncal diffusion schemes in an ocean model, but not including the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_gyre.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_gyre.json index 991c11607..5fd1e1ebf 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_gyre.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_gyre.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_gyre", + "id": "northward_ocean_heat_transport_due_to_gyre", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_gyre", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Northward transport by the ocean gyre is geometrically defined as being the part due to the vertical integral of the product of deviations of velocity and tracer from their zonal means. The velocity does not include the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_overturning.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_overturning.json index 1671018ac..810e5b54b 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_overturning.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_overturning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_overturning", + "id": "northward_ocean_heat_transport_due_to_overturning", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_overturning", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Northward transport by (meridional) overturning is geometrically defined as being the part due to the vertical integral of the product of zonal means of velocity and tracer. The velocity does not include the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_eddy_advection.json index 4bf84f1f1..717a71751 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_parameterized_eddy_advection", + "id": "northward_ocean_heat_transport_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_parameterized_eddy_advection", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection.json index 11000dbc0..b31cdb130 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection", + "id": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion.json index f1f975c12..ebe335c6d 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion", + "id": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddy diffusive processes include diffusion along neutral directions in the interior of the ocean and horizontal diffusion in the surface boundary layer. The processes occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks.", diff --git a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection.json b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection.json index d9002cf9f..6efd20d95 100644 --- a/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection", + "id": "northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection", "type": "standard_name", "name": "northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized submesoscale eddy advection occurs on a spatial scale of the order of 1 km horizontally. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. There are also standard names for parameterized_mesoscale_eddy_advection which, along with parameterized_submesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/northward_ocean_salt_transport.json b/data_descriptors/standard_name/northward_ocean_salt_transport.json index 856756757..e46a35e9b 100644 --- a/data_descriptors/standard_name/northward_ocean_salt_transport.json +++ b/data_descriptors/standard_name/northward_ocean_salt_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_salt_transport", + "id": "northward_ocean_salt_transport", "type": "standard_name", "name": "northward_ocean_salt_transport", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Ocean transport means transport by all processes, both sea water and sea ice.", diff --git a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_diffusion.json b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_diffusion.json index 2abb6b910..ed7373975 100644 --- a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_diffusion.json +++ b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_salt_transport_due_to_diffusion", + "id": "northward_ocean_salt_transport_due_to_diffusion", "type": "standard_name", "name": "northward_ocean_salt_transport_due_to_diffusion", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Salt transport\" means the mass of salt being transported. Northward transport by diffusion means the part due to horizontal or isopyncal diffusion schemes in an ocean model, but not including the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_gyre.json b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_gyre.json index 33f6267f4..24f80bd7a 100644 --- a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_gyre.json +++ b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_gyre.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_salt_transport_due_to_gyre", + "id": "northward_ocean_salt_transport_due_to_gyre", "type": "standard_name", "name": "northward_ocean_salt_transport_due_to_gyre", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Salt transport\" means the mass of salt being transported. Northward transport by the ocean gyre is geometrically defined as being the part due to the vertical integral of the product of deviations of velocity and tracer from their zonal means. The velocity does not include the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_overturning.json b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_overturning.json index e5e278ba6..dfcd2b62e 100644 --- a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_overturning.json +++ b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_overturning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_salt_transport_due_to_overturning", + "id": "northward_ocean_salt_transport_due_to_overturning", "type": "standard_name", "name": "northward_ocean_salt_transport_due_to_overturning", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Salt transport\" means the mass of salt being transported. Northward transport by (meridional) overturning is geometrically defined as being the part due to the vertical integral of the product of zonal means of velocity and tracer. The velocity does not include the parameterized eddy velocity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_parameterized_eddy_advection.json index 4c9e658a8..ca612103e 100644 --- a/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/northward_ocean_salt_transport_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_ocean_salt_transport_due_to_parameterized_eddy_advection", + "id": "northward_ocean_salt_transport_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "northward_ocean_salt_transport_due_to_parameterized_eddy_advection", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/northward_sea_ice_displacement.json b/data_descriptors/standard_name/northward_sea_ice_displacement.json index 262032442..e5ef74cdf 100644 --- a/data_descriptors/standard_name/northward_sea_ice_displacement.json +++ b/data_descriptors/standard_name/northward_sea_ice_displacement.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_ice_displacement", + "id": "northward_sea_ice_displacement", "type": "standard_name", "name": "northward_sea_ice_displacement", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Displacement\" means the change in geospatial position of an object that has moved over time. If possible, the time interval over which the motion took place should be specified using a bounds variable for the time coordinate variable. A displacement can be represented as a vector. Such a vector should however not be interpreted as describing a rectilinear, constant speed motion but merely as an indication that the start point of the vector is found at the tip of the vector after the time interval associated with the displacement variable. A displacement does not prescribe a trajectory. Sea ice displacement can be defined as a two-dimensional vector, with no vertical component. A northward displacement is the distance calculated from the change in a moving object's latitude between the start and end of the time interval associated with the displacement variable. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/northward_sea_ice_velocity.json b/data_descriptors/standard_name/northward_sea_ice_velocity.json index 59295a13b..f762942f0 100644 --- a/data_descriptors/standard_name/northward_sea_ice_velocity.json +++ b/data_descriptors/standard_name/northward_sea_ice_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_ice_velocity", + "id": "northward_sea_ice_velocity", "type": "standard_name", "name": "northward_sea_ice_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Sea ice velocity is defined as a two-dimensional vector, with no vertical component. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/northward_sea_water_velocity.json b/data_descriptors/standard_name/northward_sea_water_velocity.json index 8642b990e..1f2516c62 100644 --- a/data_descriptors/standard_name/northward_sea_water_velocity.json +++ b/data_descriptors/standard_name/northward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_water_velocity", + "id": "northward_sea_water_velocity", "type": "standard_name", "name": "northward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward).", diff --git a/data_descriptors/standard_name/northward_sea_water_velocity_assuming_no_tide.json b/data_descriptors/standard_name/northward_sea_water_velocity_assuming_no_tide.json index ace37e5d8..2b6497760 100644 --- a/data_descriptors/standard_name/northward_sea_water_velocity_assuming_no_tide.json +++ b/data_descriptors/standard_name/northward_sea_water_velocity_assuming_no_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_water_velocity_assuming_no_tide", + "id": "northward_sea_water_velocity_assuming_no_tide", "type": "standard_name", "name": "northward_sea_water_velocity_assuming_no_tide", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/northward_sea_water_velocity_at_sea_floor.json b/data_descriptors/standard_name/northward_sea_water_velocity_at_sea_floor.json index b578c4d72..24d96053e 100644 --- a/data_descriptors/standard_name/northward_sea_water_velocity_at_sea_floor.json +++ b/data_descriptors/standard_name/northward_sea_water_velocity_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_water_velocity_at_sea_floor", + "id": "northward_sea_water_velocity_at_sea_floor", "type": "standard_name", "name": "northward_sea_water_velocity_at_sea_floor", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). The velocity at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements.", diff --git a/data_descriptors/standard_name/northward_sea_water_velocity_due_to_ekman_drift.json b/data_descriptors/standard_name/northward_sea_water_velocity_due_to_ekman_drift.json index 8e1cafa4d..1d76a1e8e 100644 --- a/data_descriptors/standard_name/northward_sea_water_velocity_due_to_ekman_drift.json +++ b/data_descriptors/standard_name/northward_sea_water_velocity_due_to_ekman_drift.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_water_velocity_due_to_ekman_drift", + "id": "northward_sea_water_velocity_due_to_ekman_drift", "type": "standard_name", "name": "northward_sea_water_velocity_due_to_ekman_drift", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json b/data_descriptors/standard_name/northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json index 3009df9f8..a0d4399dc 100644 --- a/data_descriptors/standard_name/northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json +++ b/data_descriptors/standard_name/northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", + "id": "northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", "type": "standard_name", "name": "northward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddies occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddies are represented in ocean models using schemes such as the Gent-McWilliams scheme.", diff --git a/data_descriptors/standard_name/northward_sea_water_velocity_due_to_tides.json b/data_descriptors/standard_name/northward_sea_water_velocity_due_to_tides.json index 8937fd8c0..9005d4cae 100644 --- a/data_descriptors/standard_name/northward_sea_water_velocity_due_to_tides.json +++ b/data_descriptors/standard_name/northward_sea_water_velocity_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_sea_water_velocity_due_to_tides", + "id": "northward_sea_water_velocity_due_to_tides", "type": "standard_name", "name": "northward_sea_water_velocity_due_to_tides", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components.", diff --git a/data_descriptors/standard_name/northward_transformed_eulerian_mean_air_velocity.json b/data_descriptors/standard_name/northward_transformed_eulerian_mean_air_velocity.json index aa223851e..038412dc2 100644 --- a/data_descriptors/standard_name/northward_transformed_eulerian_mean_air_velocity.json +++ b/data_descriptors/standard_name/northward_transformed_eulerian_mean_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_transformed_eulerian_mean_air_velocity", + "id": "northward_transformed_eulerian_mean_air_velocity", "type": "standard_name", "name": "northward_transformed_eulerian_mean_air_velocity", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). The \"Transformed Eulerian Mean\" refers to a formulation of the mean equations which incorporates some eddy terms into the definition of the mean, described in Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", diff --git a/data_descriptors/standard_name/northward_upward_derivative_of_geopotential.json b/data_descriptors/standard_name/northward_upward_derivative_of_geopotential.json index 8628e2f15..34bf280a0 100644 --- a/data_descriptors/standard_name/northward_upward_derivative_of_geopotential.json +++ b/data_descriptors/standard_name/northward_upward_derivative_of_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_upward_derivative_of_geopotential", + "id": "northward_upward_derivative_of_geopotential", "type": "standard_name", "name": "northward_upward_derivative_of_geopotential", "description": "A quantity with standard name Xward_Yward_derivative_of_geopotential is a second spatial derivative of geopotential, P, in the direction specified by X and Y, i.e., d2P/dXdY. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude.", diff --git a/data_descriptors/standard_name/northward_water_vapor_flux_in_air.json b/data_descriptors/standard_name/northward_water_vapor_flux_in_air.json index ad319824f..747ddd2ab 100644 --- a/data_descriptors/standard_name/northward_water_vapor_flux_in_air.json +++ b/data_descriptors/standard_name/northward_water_vapor_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_water_vapor_flux_in_air", + "id": "northward_water_vapor_flux_in_air", "type": "standard_name", "name": "northward_water_vapor_flux_in_air", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json b/data_descriptors/standard_name/northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json index 64ae880ba..76afba506 100644 --- a/data_descriptors/standard_name/northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer", + "id": "northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer", "type": "standard_name", "name": "northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer", "description": "\"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.", diff --git a/data_descriptors/standard_name/northward_westward_derivative_of_geopotential.json b/data_descriptors/standard_name/northward_westward_derivative_of_geopotential.json index 6f6724f81..70bf58076 100644 --- a/data_descriptors/standard_name/northward_westward_derivative_of_geopotential.json +++ b/data_descriptors/standard_name/northward_westward_derivative_of_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_westward_derivative_of_geopotential", + "id": "northward_westward_derivative_of_geopotential", "type": "standard_name", "name": "northward_westward_derivative_of_geopotential", "description": "A quantity with standard name Xward_Yward_derivative_of_geopotential is a second spatial derivative of geopotential in the direction specified by X and Y, i.e., d2P/dXdY. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. \"Westward\" indicates a vector component which is positive when directed westward (negative eastward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude.", diff --git a/data_descriptors/standard_name/northward_wind.json b/data_descriptors/standard_name/northward_wind.json index 267ce5c00..d5cfe04a3 100644 --- a/data_descriptors/standard_name/northward_wind.json +++ b/data_descriptors/standard_name/northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/northward_wind", + "id": "northward_wind", "type": "standard_name", "name": "northward_wind", "description": "\"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/nudging_increment_in_mass_content_of_water_in_soil.json b/data_descriptors/standard_name/nudging_increment_in_mass_content_of_water_in_soil.json index 9acbc47b3..37b26501b 100644 --- a/data_descriptors/standard_name/nudging_increment_in_mass_content_of_water_in_soil.json +++ b/data_descriptors/standard_name/nudging_increment_in_mass_content_of_water_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nudging_increment_in_mass_content_of_water_in_soil", + "id": "nudging_increment_in_mass_content_of_water_in_soil", "type": "standard_name", "name": "nudging_increment_in_mass_content_of_water_in_soil", "description": "A \"nudging increment\" refers to an amount added to parts of a model system. The phrase \"nudging_increment_in_X\" refers to an increment in quantity X over a time period which should be defined in the bounds of the time coordinate. \"Content\" indicates a quantity per unit area. \"Water\" means water in all phases. The mass content of water in soil refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used.", diff --git a/data_descriptors/standard_name/nudging_increment_in_snow_and_ice_amount_on_land.json b/data_descriptors/standard_name/nudging_increment_in_snow_and_ice_amount_on_land.json index 76f010555..c5beef2c0 100644 --- a/data_descriptors/standard_name/nudging_increment_in_snow_and_ice_amount_on_land.json +++ b/data_descriptors/standard_name/nudging_increment_in_snow_and_ice_amount_on_land.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/nudging_increment_in_snow_and_ice_amount_on_land", + "id": "nudging_increment_in_snow_and_ice_amount_on_land", "type": "standard_name", "name": "nudging_increment_in_snow_and_ice_amount_on_land", "description": "A \"nudging increment\" refers to an amount added to parts of a model system. The phrase \"nudging_increment_in_X\" refers to an increment in quantity X over a time period which should be defined in the bounds of the time coordinate. \"Amount\" means mass per unit area. \"Snow and ice on land\" means ice in glaciers, ice caps, ice sheets & shelves, river and lake ice, any other ice on a land surface, such as frozen flood water, and snow lying on such ice or on the land surface.", diff --git a/data_descriptors/standard_name/number_concentration_of_aerosol_particles_at_stp_in_air.json b/data_descriptors/standard_name/number_concentration_of_aerosol_particles_at_stp_in_air.json index 540395522..2b5784e9d 100644 --- a/data_descriptors/standard_name/number_concentration_of_aerosol_particles_at_stp_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_aerosol_particles_at_stp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_aerosol_particles_at_stp_in_air", + "id": "number_concentration_of_aerosol_particles_at_stp_in_air", "type": "standard_name", "name": "number_concentration_of_aerosol_particles_at_stp_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa). The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/number_concentration_of_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_aerosol_particles_in_air.json index a6b872a85..32c8f6e2d 100644 --- a/data_descriptors/standard_name/number_concentration_of_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_aerosol_particles_in_air", + "id": "number_concentration_of_aerosol_particles_in_air", "type": "standard_name", "name": "number_concentration_of_aerosol_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself.", diff --git a/data_descriptors/standard_name/number_concentration_of_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_ambient_aerosol_particles_in_air.json index 92e3370c5..4dfc1c7fb 100644 --- a/data_descriptors/standard_name/number_concentration_of_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_ambient_aerosol_particles_in_air", + "id": "number_concentration_of_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "number_concentration_of_ambient_aerosol_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles.", diff --git a/data_descriptors/standard_name/number_concentration_of_biological_taxon_in_sea_water.json b/data_descriptors/standard_name/number_concentration_of_biological_taxon_in_sea_water.json index 985806234..f8d9aa728 100644 --- a/data_descriptors/standard_name/number_concentration_of_biological_taxon_in_sea_water.json +++ b/data_descriptors/standard_name/number_concentration_of_biological_taxon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_biological_taxon_in_sea_water", + "id": "number_concentration_of_biological_taxon_in_sea_water", "type": "standard_name", "name": "number_concentration_of_biological_taxon_in_sea_water", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_lsid to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/number_concentration_of_biological_taxon_pollen_grains_in_air.json b/data_descriptors/standard_name/number_concentration_of_biological_taxon_pollen_grains_in_air.json index dec69e33d..e5396d52a 100644 --- a/data_descriptors/standard_name/number_concentration_of_biological_taxon_pollen_grains_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_biological_taxon_pollen_grains_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_biological_taxon_pollen_grains_in_air", + "id": "number_concentration_of_biological_taxon_pollen_grains_in_air", "type": "standard_name", "name": "number_concentration_of_biological_taxon_pollen_grains_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Pollen grain\" refers to the male gametophyte of seed plants (either angiosperms or gymnosperms). The number concentration of pollen grains refers to the number of individual pollen grains per unit volume. \"Biological taxon\" is a name or other label identifying an organism or a group of organisms as belonging to a unit of classification in a hierarchical taxonomy. There must be an auxiliary coordinate variable with standard name biological_taxon_name to identify the taxon in human readable format and optionally an auxiliary coordinate variable with standard name biological_taxon_identifier to provide a machine-readable identifier. See Section 6.1.2 of the CF convention (version 1.8 or later) for information about biological taxon auxiliary coordinate variables.", diff --git a/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_at_stp_in_air.json b/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_at_stp_in_air.json index f2bd85d77..4ae640e56 100644 --- a/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_at_stp_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_at_stp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_cloud_condensation_nuclei_at_stp_in_air", + "id": "number_concentration_of_cloud_condensation_nuclei_at_stp_in_air", "type": "standard_name", "name": "number_concentration_of_cloud_condensation_nuclei_at_stp_in_air", "description": "The cloud condensation nuclei number concentration is the total number of aerosol particles per unit volume independent of and integrated over particle size that act as condensation nuclei for liquid-phase clouds. A coordinate variable with the standard name of relative_humidity should be specified to indicate that the property refers to a specific supersaturation with respect to liquid water. The ability of a particle to act as a condensation nucleus is determined by its size, chemical composition, and morphology. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa).", diff --git a/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_in_air.json b/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_in_air.json index 67799e1d9..884b3da35 100644 --- a/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_cloud_condensation_nuclei_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_cloud_condensation_nuclei_in_air", + "id": "number_concentration_of_cloud_condensation_nuclei_in_air", "type": "standard_name", "name": "number_concentration_of_cloud_condensation_nuclei_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. The cloud condensation nuclei number concentration is the total number of aerosol particles per unit volume independent of and integrated over particle size that act as condensation nuclei for liquid-phase clouds. A coordinate variable with the standard name of relative_humidity should be specified to indicate that the property refers to a specific supersaturation with respect to liquid water. The ability of a particle to act as a condensation nucleus is determined by its size, chemical composition, and morphology.", diff --git a/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air.json index 81e51cf11..823d5a1c9 100644 --- a/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_cloud_liquid_water_particles_in_air", + "id": "number_concentration_of_cloud_liquid_water_particles_in_air", "type": "standard_name", "name": "number_concentration_of_cloud_liquid_water_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top.json b/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top.json index f09b8ca03..532c6d3d2 100644 --- a/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top.json +++ b/data_descriptors/standard_name/number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top", + "id": "number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top", "type": "standard_name", "name": "number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. cloud_top refers to the top of the highest cloud.", diff --git a/data_descriptors/standard_name/number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json index 8a578599a..c917bdc5d 100644 --- a/data_descriptors/standard_name/number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", + "id": "number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. Coarse mode aerosol particles have a diameter of more than 1 micrometer.", diff --git a/data_descriptors/standard_name/number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json b/data_descriptors/standard_name/number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json index f2053ac29..86bd9e737 100644 --- a/data_descriptors/standard_name/number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json +++ b/data_descriptors/standard_name/number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top", + "id": "number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top", "type": "standard_name", "name": "number_concentration_of_convective_cloud_liquid_water_particles_at_convective_liquid_water_cloud_top", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. The phrase \"convective_liquid_water_cloud_top\" refers to the top of the highest convective liquid water cloud. Convective cloud is that produced by the convection schemes in an atmosphere model. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air.json b/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air.json index aca1e5552..c640bff9f 100644 --- a/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_ice_crystals_in_air", + "id": "number_concentration_of_ice_crystals_in_air", "type": "standard_name", "name": "number_concentration_of_ice_crystals_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume.", diff --git a/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air_at_ice_cloud_top.json b/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air_at_ice_cloud_top.json index 9cbc40966..05d002564 100644 --- a/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air_at_ice_cloud_top.json +++ b/data_descriptors/standard_name/number_concentration_of_ice_crystals_in_air_at_ice_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_ice_crystals_in_air_at_ice_cloud_top", + "id": "number_concentration_of_ice_crystals_in_air_at_ice_cloud_top", "type": "standard_name", "name": "number_concentration_of_ice_crystals_in_air_at_ice_cloud_top", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. cloud_top refers to the top of the highest cloud.", diff --git a/data_descriptors/standard_name/number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air.json index b838adfda..0568a3b2e 100644 --- a/data_descriptors/standard_name/number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air", + "id": "number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air", "type": "standard_name", "name": "number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. Nucleation mode aerosol particles have a diameter of less than 3 nanometers.", diff --git a/data_descriptors/standard_name/number_concentration_of_ozone_molecules_in_air.json b/data_descriptors/standard_name/number_concentration_of_ozone_molecules_in_air.json index f77ada341..09e7930e5 100644 --- a/data_descriptors/standard_name/number_concentration_of_ozone_molecules_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_ozone_molecules_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_ozone_molecules_in_air", + "id": "number_concentration_of_ozone_molecules_in_air", "type": "standard_name", "name": "number_concentration_of_ozone_molecules_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/number_concentration_of_pm10_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_pm10_aerosol_particles_in_air.json index ec7d3e51b..585588d1d 100644 --- a/data_descriptors/standard_name/number_concentration_of_pm10_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_pm10_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_pm10_aerosol_particles_in_air", + "id": "number_concentration_of_pm10_aerosol_particles_in_air", "type": "standard_name", "name": "number_concentration_of_pm10_aerosol_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of, respectively, \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/number_concentration_of_pm2p5_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_concentration_of_pm2p5_aerosol_particles_in_air.json index c6d2e9310..377f099da 100644 --- a/data_descriptors/standard_name/number_concentration_of_pm2p5_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_concentration_of_pm2p5_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_pm2p5_aerosol_particles_in_air", + "id": "number_concentration_of_pm2p5_aerosol_particles_in_air", "type": "standard_name", "name": "number_concentration_of_pm2p5_aerosol_particles_in_air", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of, respectively, \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json b/data_descriptors/standard_name/number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json index df39a0c67..1ce83285e 100644 --- a/data_descriptors/standard_name/number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json +++ b/data_descriptors/standard_name/number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top", + "id": "number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top", "type": "standard_name", "name": "number_concentration_of_stratiform_cloud_liquid_water_particles_at_stratiform_liquid_water_cloud_top", "description": "\"Number concentration\" means the number of particles or other specified objects per unit volume. The phrase \"stratiform_liquid_water_cloud_top\" refers to the top of the highest stratiform liquid water cloud. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/number_of_days_with_air_temperature_above_threshold.json b/data_descriptors/standard_name/number_of_days_with_air_temperature_above_threshold.json index 4f36caa29..33fc7b07e 100644 --- a/data_descriptors/standard_name/number_of_days_with_air_temperature_above_threshold.json +++ b/data_descriptors/standard_name/number_of_days_with_air_temperature_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_days_with_air_temperature_above_threshold", + "id": "number_of_days_with_air_temperature_above_threshold", "type": "standard_name", "name": "number_of_days_with_air_temperature_above_threshold", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A variable whose standard name has the form number_of_days_with_X_below|above_threshold is a count of the number of days on which the condition X_below|above_threshold is satisfied. It must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_methods entry for within days which describes the processing of quantity X before the threshold is applied. A number_of_days is an extensive quantity in time, and the cell_methods entry for over days should be \"sum\".", diff --git a/data_descriptors/standard_name/number_of_days_with_air_temperature_below_threshold.json b/data_descriptors/standard_name/number_of_days_with_air_temperature_below_threshold.json index 3d5f73c93..8380574e9 100644 --- a/data_descriptors/standard_name/number_of_days_with_air_temperature_below_threshold.json +++ b/data_descriptors/standard_name/number_of_days_with_air_temperature_below_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_days_with_air_temperature_below_threshold", + "id": "number_of_days_with_air_temperature_below_threshold", "type": "standard_name", "name": "number_of_days_with_air_temperature_below_threshold", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A variable whose standard name has the form number_of_days_with_X_below|above_threshold is a count of the number of days on which the condition X_below|above_threshold is satisfied. It must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_methods entry for within days which describes the processing of quantity X before the threshold is applied. A number_of_days is an extensive quantity in time, and the cell_methods entry for over days should be \"sum\".", diff --git a/data_descriptors/standard_name/number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json b/data_descriptors/standard_name/number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json index 072bfd611..3fc2f2eb9 100644 --- a/data_descriptors/standard_name/number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json +++ b/data_descriptors/standard_name/number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold", + "id": "number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold", "type": "standard_name", "name": "number_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold", "description": "The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The abbreviation \"lwe\" means liquid water equivalent. A variable whose standard name has the form number_of_days_with_X_below|above_threshold is a count of the number of days on which the condition X_below|above_threshold is satisfied. It must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_methods entry for within days which describes the processing of quantity X before the threshold is applied. A number_of_days is an extensive quantity in time, and the cell_methods entry for over days should be \"sum\".", diff --git a/data_descriptors/standard_name/number_of_days_with_surface_temperature_below_threshold.json b/data_descriptors/standard_name/number_of_days_with_surface_temperature_below_threshold.json index 77bf9f9bf..e60814198 100644 --- a/data_descriptors/standard_name/number_of_days_with_surface_temperature_below_threshold.json +++ b/data_descriptors/standard_name/number_of_days_with_surface_temperature_below_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_days_with_surface_temperature_below_threshold", + "id": "number_of_days_with_surface_temperature_below_threshold", "type": "standard_name", "name": "number_of_days_with_surface_temperature_below_threshold", "description": "The surface temperature is the temperature at the interface, not the bulk temperature of the medium above or below. The surface called \"surface\" means the lower boundary of the atmosphere. A variable whose standard name has the form number_of_days_with_X_below|above_threshold is a count of the number of days on which the condition X_below|above_threshold is satisfied. It must have a coordinate variable or scalar coordinate variable with the a standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_methods entry for within days which describes the processing of quantity X before the threshold is applied. A number_of_days is an extensive quantity in time, and the cell_methods entry for over days should be \"sum\".", diff --git a/data_descriptors/standard_name/number_of_days_with_wind_speed_above_threshold.json b/data_descriptors/standard_name/number_of_days_with_wind_speed_above_threshold.json index c8d9f0e0e..f70de232a 100644 --- a/data_descriptors/standard_name/number_of_days_with_wind_speed_above_threshold.json +++ b/data_descriptors/standard_name/number_of_days_with_wind_speed_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_days_with_wind_speed_above_threshold", + "id": "number_of_days_with_wind_speed_above_threshold", "type": "standard_name", "name": "number_of_days_with_wind_speed_above_threshold", "description": "Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. A variable whose standard name has the form number_of_days_with_X_below|above_threshold is a count of the number of days on which the condition X_below|above_threshold is satisfied. It must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_methods entry for within days which describes the processing of quantity X before the threshold is applied. A number_of_days is an extensive quantity in time, and the cell_methods entry for over days should be \"sum\".", diff --git a/data_descriptors/standard_name/number_of_icebergs_per_unit_area.json b/data_descriptors/standard_name/number_of_icebergs_per_unit_area.json index 9f132babe..4f533eaeb 100644 --- a/data_descriptors/standard_name/number_of_icebergs_per_unit_area.json +++ b/data_descriptors/standard_name/number_of_icebergs_per_unit_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_icebergs_per_unit_area", + "id": "number_of_icebergs_per_unit_area", "type": "standard_name", "name": "number_of_icebergs_per_unit_area", "description": "The number of icebergs per unit area.", diff --git a/data_descriptors/standard_name/number_of_missing_observations.json b/data_descriptors/standard_name/number_of_missing_observations.json index c1d4ca402..c678e3da7 100644 --- a/data_descriptors/standard_name/number_of_missing_observations.json +++ b/data_descriptors/standard_name/number_of_missing_observations.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_missing_observations", + "id": "number_of_missing_observations", "type": "standard_name", "name": "number_of_missing_observations", "description": "A variable with the standard name of number_of_missing_observations contains the number of discrete observations or measurements that were not available to derive the values of another data variable. The linkage between the data variable and the variable with a standard_name of number_of_missing_observations is achieved using the ancillary_variables attribute.", diff --git a/data_descriptors/standard_name/number_of_observations.json b/data_descriptors/standard_name/number_of_observations.json index 79d889ee7..f0f665b10 100644 --- a/data_descriptors/standard_name/number_of_observations.json +++ b/data_descriptors/standard_name/number_of_observations.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_of_observations", + "id": "number_of_observations", "type": "standard_name", "name": "number_of_observations", "description": "A variable with the standard name of number_of_observations contains the number of discrete observations or measurements from which the values of another data variable have been derived. The linkage between the data variable and the variable with a standard_name of number_of_observations is achieved using the ancillary_variables attribute.", diff --git a/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_at_stp_in_air.json b/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_at_stp_in_air.json index cb9db9299..3e917a025 100644 --- a/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_at_stp_in_air.json +++ b/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_at_stp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_size_distribution_of_aerosol_particles_at_stp_in_air", + "id": "number_size_distribution_of_aerosol_particles_at_stp_in_air", "type": "standard_name", "name": "number_size_distribution_of_aerosol_particles_at_stp_in_air", "description": "The aerosol particle number size distribution is the number concentration of aerosol particles as a function of particle diameter. A coordinate variable with the standard name of electrical_mobility_particle_diameter, aerodynamic_particle_diameter, or optical_particle_diameter should be specified to indicate that the property applies at specific particle sizes selected by the indicated method. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. \"log10_X\" means common logarithm (i.e. base 10) of X. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa).", diff --git a/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_in_air.json b/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_in_air.json index 24bee3190..dac742b8d 100644 --- a/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_in_air.json +++ b/data_descriptors/standard_name/number_size_distribution_of_aerosol_particles_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_size_distribution_of_aerosol_particles_in_air", + "id": "number_size_distribution_of_aerosol_particles_in_air", "type": "standard_name", "name": "number_size_distribution_of_aerosol_particles_in_air", "description": "The aerosol particle number size distribution is the number concentration of aerosol particles as a function of particle diameter. A coordinate variable with the standard name of electrical_mobility_particle_diameter, aerodynamic_particle_diameter, or optical_particle_diameter should be specified to indicate that the property applies at specific particle sizes selected by the indicated method. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection.", diff --git a/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json b/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json index 580599690..f3c0a3755 100644 --- a/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json +++ b/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air", + "id": "number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air", "type": "standard_name", "name": "number_size_distribution_of_cloud_condensation_nuclei_at_stp_in_air", "description": "The cloud condensation nuclei number size distribution is the number concentration of aerosol particles as a function of particle diameter, where the particle acts as condensation nucleus for liquid-phase clouds. A coordinate variable with the standard name of relative_humidity should be specified to indicate that the property refers to a specific supersaturation with respect to liquid water. A coordinate variable with the standard name of electrical_mobility_particle_diameter should be specified to indicate that the property applies at specific mobility particle sizes. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. The ability of a particle to act as a condensation nucleus is determined by its size, chemical composition, and morphology. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa).", diff --git a/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_in_air.json b/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_in_air.json index fc6901710..7f004bfb9 100644 --- a/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_in_air.json +++ b/data_descriptors/standard_name/number_size_distribution_of_cloud_condensation_nuclei_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/number_size_distribution_of_cloud_condensation_nuclei_in_air", + "id": "number_size_distribution_of_cloud_condensation_nuclei_in_air", "type": "standard_name", "name": "number_size_distribution_of_cloud_condensation_nuclei_in_air", "description": "The cloud condensation nuclei number size distribution is the number concentration of aerosol particles as a function of particle diameter, where the particle acts as condensation nucleus for liquid-phase clouds. A coordinate variable with the standard name of relative_humidity should be specified to indicate that the property refers to a specific supersaturation with respect to liquid water. A coordinate variable with the standard name of electrical_mobility_particle_diameter should be specified to indicate that the property applies at specific mobility particle sizes. To specify the relative humidity at which the particle sizes were selected, provide a scalar coordinate variable with the standard name of relative_humidity_for_aerosol_particle_size_selection. The ability of a particle to act as a condensation nucleus is determined by its size, chemical composition, and morphology.", diff --git a/data_descriptors/standard_name/ocean_barotropic_mass_streamfunction.json b/data_descriptors/standard_name/ocean_barotropic_mass_streamfunction.json index 7d838c590..e2b365bb8 100644 --- a/data_descriptors/standard_name/ocean_barotropic_mass_streamfunction.json +++ b/data_descriptors/standard_name/ocean_barotropic_mass_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_barotropic_mass_streamfunction", + "id": "ocean_barotropic_mass_streamfunction", "type": "standard_name", "name": "ocean_barotropic_mass_streamfunction", "description": "The barotropic stream function with the dimensions of volume transport has the standard name ocean_barotropic_streamfunction.", diff --git a/data_descriptors/standard_name/ocean_barotropic_streamfunction.json b/data_descriptors/standard_name/ocean_barotropic_streamfunction.json index f9d7dba41..e54a43b45 100644 --- a/data_descriptors/standard_name/ocean_barotropic_streamfunction.json +++ b/data_descriptors/standard_name/ocean_barotropic_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_barotropic_streamfunction", + "id": "ocean_barotropic_streamfunction", "type": "standard_name", "name": "ocean_barotropic_streamfunction", "description": null, diff --git a/data_descriptors/standard_name/ocean_double_sigma_coordinate.json b/data_descriptors/standard_name/ocean_double_sigma_coordinate.json index 36c46f40f..c045ac536 100644 --- a/data_descriptors/standard_name/ocean_double_sigma_coordinate.json +++ b/data_descriptors/standard_name/ocean_double_sigma_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_double_sigma_coordinate", + "id": "ocean_double_sigma_coordinate", "type": "standard_name", "name": "ocean_double_sigma_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/ocean_dynamic_sea_level.json b/data_descriptors/standard_name/ocean_dynamic_sea_level.json index c16708e6d..bbda30da0 100644 --- a/data_descriptors/standard_name/ocean_dynamic_sea_level.json +++ b/data_descriptors/standard_name/ocean_dynamic_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_dynamic_sea_level", + "id": "ocean_dynamic_sea_level", "type": "standard_name", "name": "ocean_dynamic_sea_level", "description": "Ocean dynamic sea level is the contribution to sea surface height variability made by processes other than astronomic forcing of the ocean and shallow water resonance of tidal components, or variations in air pressure. Sea surface height is a time-varying quantity.", diff --git a/data_descriptors/standard_name/ocean_heat_x_transport.json b/data_descriptors/standard_name/ocean_heat_x_transport.json index 8071c9e90..409253830 100644 --- a/data_descriptors/standard_name/ocean_heat_x_transport.json +++ b/data_descriptors/standard_name/ocean_heat_x_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_heat_x_transport", + "id": "ocean_heat_x_transport", "type": "standard_name", "name": "ocean_heat_x_transport", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x.", diff --git a/data_descriptors/standard_name/ocean_heat_x_transport_due_to_diffusion.json b/data_descriptors/standard_name/ocean_heat_x_transport_due_to_diffusion.json index 3f05fd747..fbc7e49ee 100644 --- a/data_descriptors/standard_name/ocean_heat_x_transport_due_to_diffusion.json +++ b/data_descriptors/standard_name/ocean_heat_x_transport_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_heat_x_transport_due_to_diffusion", + "id": "ocean_heat_x_transport_due_to_diffusion", "type": "standard_name", "name": "ocean_heat_x_transport_due_to_diffusion", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ocean_heat_x_transport_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/ocean_heat_x_transport_due_to_parameterized_eddy_advection.json index 625a48999..cb6b0ce88 100644 --- a/data_descriptors/standard_name/ocean_heat_x_transport_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_heat_x_transport_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_heat_x_transport_due_to_parameterized_eddy_advection", + "id": "ocean_heat_x_transport_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "ocean_heat_x_transport_due_to_parameterized_eddy_advection", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_heat_y_transport.json b/data_descriptors/standard_name/ocean_heat_y_transport.json index 1ebaefb94..0996a5fc6 100644 --- a/data_descriptors/standard_name/ocean_heat_y_transport.json +++ b/data_descriptors/standard_name/ocean_heat_y_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_heat_y_transport", + "id": "ocean_heat_y_transport", "type": "standard_name", "name": "ocean_heat_y_transport", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y.", diff --git a/data_descriptors/standard_name/ocean_heat_y_transport_due_to_diffusion.json b/data_descriptors/standard_name/ocean_heat_y_transport_due_to_diffusion.json index b0f917a4b..3cde17c5b 100644 --- a/data_descriptors/standard_name/ocean_heat_y_transport_due_to_diffusion.json +++ b/data_descriptors/standard_name/ocean_heat_y_transport_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_heat_y_transport_due_to_diffusion", + "id": "ocean_heat_y_transport_due_to_diffusion", "type": "standard_name", "name": "ocean_heat_y_transport_due_to_diffusion", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ocean_heat_y_transport_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/ocean_heat_y_transport_due_to_parameterized_eddy_advection.json index c8091aad0..35d2af189 100644 --- a/data_descriptors/standard_name/ocean_heat_y_transport_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_heat_y_transport_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_heat_y_transport_due_to_parameterized_eddy_advection", + "id": "ocean_heat_y_transport_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "ocean_heat_y_transport_due_to_parameterized_eddy_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_isopycnal_layer_thickness_diffusivity.json b/data_descriptors/standard_name/ocean_isopycnal_layer_thickness_diffusivity.json index 098ef0395..4435f0cd8 100644 --- a/data_descriptors/standard_name/ocean_isopycnal_layer_thickness_diffusivity.json +++ b/data_descriptors/standard_name/ocean_isopycnal_layer_thickness_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_isopycnal_layer_thickness_diffusivity", + "id": "ocean_isopycnal_layer_thickness_diffusivity", "type": "standard_name", "name": "ocean_isopycnal_layer_thickness_diffusivity", "description": null, diff --git a/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction.json b/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction.json index 99eadeb11..abd6d176f 100644 --- a/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction.json +++ b/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction", + "id": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction", "type": "standard_name", "name": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction", "description": "Friction, leading to the dissipation of kinetic energy, arises in ocean models as a result of the viscosity of sea water. Generally, the lateral (xy) viscosity is given a large value to maintain the numerical stability of the model. In contrast, the vertical viscosity is usually much smaller. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction.json b/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction.json index 86d6af4a5..90e42a96f 100644 --- a/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction.json +++ b/data_descriptors/standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction", + "id": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction", "type": "standard_name", "name": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction", "description": "Friction, leading to the dissipation of kinetic energy, arises in ocean models as a result of the viscosity of sea water. Generally, the lateral (xy) viscosity is given a large value to maintain the numerical stability of the model. In contrast, the vertical viscosity is usually much smaller. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ocean_mass_content_of_dissolved_inorganic_carbon.json b/data_descriptors/standard_name/ocean_mass_content_of_dissolved_inorganic_carbon.json index 8a387446f..3b8e73da9 100644 --- a/data_descriptors/standard_name/ocean_mass_content_of_dissolved_inorganic_carbon.json +++ b/data_descriptors/standard_name/ocean_mass_content_of_dissolved_inorganic_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_content_of_dissolved_inorganic_carbon", + "id": "ocean_mass_content_of_dissolved_inorganic_carbon", "type": "standard_name", "name": "ocean_mass_content_of_dissolved_inorganic_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/ocean_mass_content_of_dissolved_organic_carbon.json b/data_descriptors/standard_name/ocean_mass_content_of_dissolved_organic_carbon.json index d6bf7a98a..022c09e39 100644 --- a/data_descriptors/standard_name/ocean_mass_content_of_dissolved_organic_carbon.json +++ b/data_descriptors/standard_name/ocean_mass_content_of_dissolved_organic_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_content_of_dissolved_organic_carbon", + "id": "ocean_mass_content_of_dissolved_organic_carbon", "type": "standard_name", "name": "ocean_mass_content_of_dissolved_organic_carbon", "description": "\"Content\" indicates a quantity per unit area. Organic carbon describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon.json b/data_descriptors/standard_name/ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon.json index 4d0fa777c..50fdc35de 100644 --- a/data_descriptors/standard_name/ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon.json +++ b/data_descriptors/standard_name/ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon", + "id": "ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon", "type": "standard_name", "name": "ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon", "description": "\"Content\" indicates a quantity per unit area. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/ocean_mass_x_transport.json b/data_descriptors/standard_name/ocean_mass_x_transport.json index 2a504686b..51185984b 100644 --- a/data_descriptors/standard_name/ocean_mass_x_transport.json +++ b/data_descriptors/standard_name/ocean_mass_x_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_x_transport", + "id": "ocean_mass_x_transport", "type": "standard_name", "name": "ocean_mass_x_transport", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x.", diff --git a/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection.json b/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection.json index 6d60e660b..12c0d6c32 100644 --- a/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection.json +++ b/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_x_transport_due_to_advection", + "id": "ocean_mass_x_transport_due_to_advection", "type": "standard_name", "name": "ocean_mass_x_transport_due_to_advection", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection.json b/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection.json index a2a8dab74..cad8991d9 100644 --- a/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection", + "id": "ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection", "type": "standard_name", "name": "ocean_mass_x_transport_due_to_advection_and_parameterized_eddy_advection", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_mass_y_transport.json b/data_descriptors/standard_name/ocean_mass_y_transport.json index a1fee37ff..8ecdd1d10 100644 --- a/data_descriptors/standard_name/ocean_mass_y_transport.json +++ b/data_descriptors/standard_name/ocean_mass_y_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_y_transport", + "id": "ocean_mass_y_transport", "type": "standard_name", "name": "ocean_mass_y_transport", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y.", diff --git a/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection.json b/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection.json index 8dbc4c1e6..3dc948ac0 100644 --- a/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection.json +++ b/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_y_transport_due_to_advection", + "id": "ocean_mass_y_transport_due_to_advection", "type": "standard_name", "name": "ocean_mass_y_transport_due_to_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection.json b/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection.json index 52ede58ac..607b0dc52 100644 --- a/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection", + "id": "ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection", "type": "standard_name", "name": "ocean_mass_y_transport_due_to_advection_and_parameterized_eddy_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction.json b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction.json index 6f5d5bbc0..713cf9da9 100644 --- a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction.json +++ b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_meridional_overturning_mass_streamfunction", + "id": "ocean_meridional_overturning_mass_streamfunction", "type": "standard_name", "name": "ocean_meridional_overturning_mass_streamfunction", "description": "In contrast to the quantity with standard name ocean_meridional_overturning_streamfunction, this quantity includes all physical processes, resolved or parameterized, that impact mass/volume transport. Thus it includes contributions from the parameterized eddy velocity.", diff --git a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json index 9fa3c751b..401b0a43e 100644 --- a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection", + "id": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_eddy_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json index 9e3ee9ef4..465e2152a 100644 --- a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", + "id": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json index 86ffe9b2e..14fe804be 100644 --- a/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", + "id": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", "type": "standard_name", "name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized submesoscale eddy advection occurs on a spatial scale of the order of 1 km horizontally. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. There are also standard names for parameterized_mesoscale_eddy_advection which, along with parameterized_submesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_meridional_overturning_streamfunction.json b/data_descriptors/standard_name/ocean_meridional_overturning_streamfunction.json index f381b9ff2..da40788b4 100644 --- a/data_descriptors/standard_name/ocean_meridional_overturning_streamfunction.json +++ b/data_descriptors/standard_name/ocean_meridional_overturning_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_meridional_overturning_streamfunction", + "id": "ocean_meridional_overturning_streamfunction", "type": "standard_name", "name": "ocean_meridional_overturning_streamfunction", "description": "The ocean meridional overturning streamfunction should not include not include the parameterized eddy advection velocity.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness.json index 5462c814f..812f769b1 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness", + "id": "ocean_mixed_layer_thickness", "type": "standard_name", "name": "ocean_mixed_layer_thickness", "description": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. Various criteria are used to define the mixed layer; this can be specified by using a standard name of ocean_mixed_layer_defined_by_X. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_mixing_scheme.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_mixing_scheme.json index 3637836fa..667b7ae06 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_mixing_scheme.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_mixing_scheme.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness_defined_by_mixing_scheme", + "id": "ocean_mixed_layer_thickness_defined_by_mixing_scheme", "type": "standard_name", "name": "ocean_mixed_layer_thickness_defined_by_mixing_scheme", "description": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by the mixing scheme is a diagnostic of ocean models. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_t.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_t.json index a698a92ca..226185662 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_t.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_t.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness_defined_by_sigma_t", + "id": "ocean_mixed_layer_thickness_defined_by_sigma_t", "type": "standard_name", "name": "ocean_mixed_layer_thickness_defined_by_sigma_t", "description": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by \"temperature\", \"sigma\", \"sigma_theta\", \"sigma_t\" or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_sigma_t_difference can be used to specify the sigma_t criterion that determines the layer thickness. Sigma-t of sea water is the density of water at atmospheric pressure (i.e. the surface) having the same temperature and salinity, minus 1000 kg m-3. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_theta.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_theta.json index 8b45bbd08..2c90f29ac 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_theta.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_sigma_theta.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness_defined_by_sigma_theta", + "id": "ocean_mixed_layer_thickness_defined_by_sigma_theta", "type": "standard_name", "name": "ocean_mixed_layer_thickness_defined_by_sigma_theta", "description": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by \"temperature\", \"sigma\", \"sigma_theta\", \"sigma_t\" or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_sigma_theta_difference can be used to specify the sigma_theta criterion that determines the layer thickness. Sigma-theta of sea water is the potential density (i.e. the density when moved adiabatically to a reference pressure) of water having the same temperature and salinity, minus 1000 kg m-3. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_temperature.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_temperature.json index c4b260029..4f13a4a8d 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_temperature.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness_defined_by_temperature", + "id": "ocean_mixed_layer_thickness_defined_by_temperature", "type": "standard_name", "name": "ocean_mixed_layer_thickness_defined_by_temperature", "description": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by \"temperature\", \"sigma\", \"sigma_theta\", \"sigma_t\" or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_temperature_difference can be used to specify the temperature criterion that determines the layer thickness. Sea water temperature is the in situ temperature of the sea water. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit.json index c03a8124d..c8a462130 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit", + "id": "ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit", "type": "standard_name", "name": "ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_deficit", "description": "\"Thickness\" means the vertical extent of a layer. The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by temperature, sigma, sigma_theta, or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. The amount by which the quantity differs can be specified by a scalar coordinate variable.", diff --git a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold.json b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold.json index 228200496..72ff09b27 100644 --- a/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold.json +++ b/data_descriptors/standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold", + "id": "ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold", "type": "standard_name", "name": "ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity_threshold", "description": "\"Thickness\" means the vertical extent of a layer. The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. The diffusivity threshold should be specified by associating a coordinate variable or scalar coordinate variable with the data variable and giving the coordinate variable a standard name of ocean_vertical_tracer_diffusivity.", diff --git a/data_descriptors/standard_name/ocean_momentum_xy_biharmonic_diffusivity.json b/data_descriptors/standard_name/ocean_momentum_xy_biharmonic_diffusivity.json index 5a8fdc16e..d3e2e8d3a 100644 --- a/data_descriptors/standard_name/ocean_momentum_xy_biharmonic_diffusivity.json +++ b/data_descriptors/standard_name/ocean_momentum_xy_biharmonic_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_momentum_xy_biharmonic_diffusivity", + "id": "ocean_momentum_xy_biharmonic_diffusivity", "type": "standard_name", "name": "ocean_momentum_xy_biharmonic_diffusivity", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"xy diffusivity\" means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. \"biharmonic diffusivity\" means diffusivity for use with a biharmonic diffusion operator.", diff --git a/data_descriptors/standard_name/ocean_momentum_xy_laplacian_diffusivity.json b/data_descriptors/standard_name/ocean_momentum_xy_laplacian_diffusivity.json index 1ad022647..7c9ef77dc 100644 --- a/data_descriptors/standard_name/ocean_momentum_xy_laplacian_diffusivity.json +++ b/data_descriptors/standard_name/ocean_momentum_xy_laplacian_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_momentum_xy_laplacian_diffusivity", + "id": "ocean_momentum_xy_laplacian_diffusivity", "type": "standard_name", "name": "ocean_momentum_xy_laplacian_diffusivity", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"xy diffusivity\" means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. \"laplacian diffusivity\" means diffusivity for use with a Laplacian diffusion operator.", diff --git a/data_descriptors/standard_name/ocean_montgomery_potential.json b/data_descriptors/standard_name/ocean_montgomery_potential.json index 03b7516f0..41372be96 100644 --- a/data_descriptors/standard_name/ocean_montgomery_potential.json +++ b/data_descriptors/standard_name/ocean_montgomery_potential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_montgomery_potential", + "id": "ocean_montgomery_potential", "type": "standard_name", "name": "ocean_montgomery_potential", "description": "Montgomery potential is defined as M = ap + gz, where a = specific volume, p = pressure, g = gravity, and z=depth. It represents an exact streamfunction on specific volume anomaly surfaces.", diff --git a/data_descriptors/standard_name/ocean_obukhov_length.json b/data_descriptors/standard_name/ocean_obukhov_length.json index d15930017..9e8dc37b7 100644 --- a/data_descriptors/standard_name/ocean_obukhov_length.json +++ b/data_descriptors/standard_name/ocean_obukhov_length.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_obukhov_length", + "id": "ocean_obukhov_length", "type": "standard_name", "name": "ocean_obukhov_length", "description": "The depth in the ocean, L, that buoyant production or destruction of turbulent energy balances the turbulent kinetic energy: L = -u*3 / (kB0), where u* is the oceanic surface frictional velocity, k is the von Karman constant, and B0 is the oceanic surface buoyancy flux. If the buoyancy flux is destabilizing, L is negative.", diff --git a/data_descriptors/standard_name/ocean_relative_vorticity.json b/data_descriptors/standard_name/ocean_relative_vorticity.json index fa0574c6f..af0d3985d 100644 --- a/data_descriptors/standard_name/ocean_relative_vorticity.json +++ b/data_descriptors/standard_name/ocean_relative_vorticity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_relative_vorticity", + "id": "ocean_relative_vorticity", "type": "standard_name", "name": "ocean_relative_vorticity", "description": "Relative vorticity is the upward component of the relative vorticity vector i.e. the component which arises from horizontal velocity.", diff --git a/data_descriptors/standard_name/ocean_rigid_lid_pressure.json b/data_descriptors/standard_name/ocean_rigid_lid_pressure.json index 048a5fff0..34c22a49b 100644 --- a/data_descriptors/standard_name/ocean_rigid_lid_pressure.json +++ b/data_descriptors/standard_name/ocean_rigid_lid_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_rigid_lid_pressure", + "id": "ocean_rigid_lid_pressure", "type": "standard_name", "name": "ocean_rigid_lid_pressure", "description": "\"Ocean rigid lid pressure\" means the pressure at the surface of an ocean model assuming that it is bounded above by a rigid lid.", diff --git a/data_descriptors/standard_name/ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid.json b/data_descriptors/standard_name/ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid.json index 832c3946f..44aebdb44 100644 --- a/data_descriptors/standard_name/ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid.json +++ b/data_descriptors/standard_name/ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid", + "id": "ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid", "type": "standard_name", "name": "ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid", "description": "\"Ocean rigid lid pressure\" means the pressure at the surface of an ocean model assuming that it is bounded above by a rigid lid. \"Sea surface height\" is a time-varying quantity. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/ocean_s_coordinate.json b/data_descriptors/standard_name/ocean_s_coordinate.json index 03f4d39c0..5fee7c034 100644 --- a/data_descriptors/standard_name/ocean_s_coordinate.json +++ b/data_descriptors/standard_name/ocean_s_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_s_coordinate", + "id": "ocean_s_coordinate", "type": "standard_name", "name": "ocean_s_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/ocean_s_coordinate_g1.json b/data_descriptors/standard_name/ocean_s_coordinate_g1.json index 9c9ed5767..e2fdc0db7 100644 --- a/data_descriptors/standard_name/ocean_s_coordinate_g1.json +++ b/data_descriptors/standard_name/ocean_s_coordinate_g1.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_s_coordinate_g1", + "id": "ocean_s_coordinate_g1", "type": "standard_name", "name": "ocean_s_coordinate_g1", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/ocean_s_coordinate_g2.json b/data_descriptors/standard_name/ocean_s_coordinate_g2.json index ee6a38f17..e2039ad18 100644 --- a/data_descriptors/standard_name/ocean_s_coordinate_g2.json +++ b/data_descriptors/standard_name/ocean_s_coordinate_g2.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_s_coordinate_g2", + "id": "ocean_s_coordinate_g2", "type": "standard_name", "name": "ocean_s_coordinate_g2", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/ocean_salt_x_transport.json b/data_descriptors/standard_name/ocean_salt_x_transport.json index dba87e7f4..858508d57 100644 --- a/data_descriptors/standard_name/ocean_salt_x_transport.json +++ b/data_descriptors/standard_name/ocean_salt_x_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_salt_x_transport", + "id": "ocean_salt_x_transport", "type": "standard_name", "name": "ocean_salt_x_transport", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. Salt transport refers to the mass of salt being transported.", diff --git a/data_descriptors/standard_name/ocean_salt_y_transport.json b/data_descriptors/standard_name/ocean_salt_y_transport.json index 264cad26e..2732f9660 100644 --- a/data_descriptors/standard_name/ocean_salt_y_transport.json +++ b/data_descriptors/standard_name/ocean_salt_y_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_salt_y_transport", + "id": "ocean_salt_y_transport", "type": "standard_name", "name": "ocean_salt_y_transport", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. Salt transport refers to the mass of salt being transported.", diff --git a/data_descriptors/standard_name/ocean_sigma_coordinate.json b/data_descriptors/standard_name/ocean_sigma_coordinate.json index 2c665ae25..9c9d9d17c 100644 --- a/data_descriptors/standard_name/ocean_sigma_coordinate.json +++ b/data_descriptors/standard_name/ocean_sigma_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_sigma_coordinate", + "id": "ocean_sigma_coordinate", "type": "standard_name", "name": "ocean_sigma_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates. Note that the ocean sigma coordinate is not the same quantity as sea water sigma (excess of density over 1000 kg m-3), for which there are various other standard names.", diff --git a/data_descriptors/standard_name/ocean_sigma_z_coordinate.json b/data_descriptors/standard_name/ocean_sigma_z_coordinate.json index 53a6068c9..ef4dfa37c 100644 --- a/data_descriptors/standard_name/ocean_sigma_z_coordinate.json +++ b/data_descriptors/standard_name/ocean_sigma_z_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_sigma_z_coordinate", + "id": "ocean_sigma_z_coordinate", "type": "standard_name", "name": "ocean_sigma_z_coordinate", "description": "See Appendix D of the CF convention for information about parametric vertical coordinates.", diff --git a/data_descriptors/standard_name/ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json index 85e3f43c2..adb3ec2f6 100644 --- a/data_descriptors/standard_name/ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection", + "id": "ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"biharmonicdiffusivity\" means diffusivity for use with a biharmonic diffusion operator. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json index f1d80e36e..948f2f8e1 100644 --- a/data_descriptors/standard_name/ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection", + "id": "ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "ocean_tracer_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_tracer_epineutral_biharmonic_diffusivity.json b/data_descriptors/standard_name/ocean_tracer_epineutral_biharmonic_diffusivity.json index a3999cf96..7198aa399 100644 --- a/data_descriptors/standard_name/ocean_tracer_epineutral_biharmonic_diffusivity.json +++ b/data_descriptors/standard_name/ocean_tracer_epineutral_biharmonic_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_epineutral_biharmonic_diffusivity", + "id": "ocean_tracer_epineutral_biharmonic_diffusivity", "type": "standard_name", "name": "ocean_tracer_epineutral_biharmonic_diffusivity", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"epineutral diffusivity\" means a lateral diffusivity along a either a neutral or isopycnal density surface due to motion which is not resolved on the grid scale of an ocean model. The type of density surface is dependent on the model formulation. \"biharmonic diffusivity\" means diffusivity for use with a biharmonic diffusion operator.", diff --git a/data_descriptors/standard_name/ocean_tracer_epineutral_laplacian_diffusivity.json b/data_descriptors/standard_name/ocean_tracer_epineutral_laplacian_diffusivity.json index 9d052376d..c30948daf 100644 --- a/data_descriptors/standard_name/ocean_tracer_epineutral_laplacian_diffusivity.json +++ b/data_descriptors/standard_name/ocean_tracer_epineutral_laplacian_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_epineutral_laplacian_diffusivity", + "id": "ocean_tracer_epineutral_laplacian_diffusivity", "type": "standard_name", "name": "ocean_tracer_epineutral_laplacian_diffusivity", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"epineutral diffusivity\" means a lateral diffusivity along a either a neutral or isopycnal density surface due to motion which is not resolved on the grid scale of an ocean model. The type of density surface is dependent on the model formulation. \"laplacian diffusivity\" means diffusivity for use with a Laplacian diffusion operator.", diff --git a/data_descriptors/standard_name/ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json index 8ee9fbf0c..feead68ac 100644 --- a/data_descriptors/standard_name/ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection", + "id": "ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"laplacian diffusivity\" means diffusivity for use with a Laplacian diffusion operator. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_tracer_xy_biharmonic_diffusivity.json b/data_descriptors/standard_name/ocean_tracer_xy_biharmonic_diffusivity.json index 163188410..eb05bfe21 100644 --- a/data_descriptors/standard_name/ocean_tracer_xy_biharmonic_diffusivity.json +++ b/data_descriptors/standard_name/ocean_tracer_xy_biharmonic_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_xy_biharmonic_diffusivity", + "id": "ocean_tracer_xy_biharmonic_diffusivity", "type": "standard_name", "name": "ocean_tracer_xy_biharmonic_diffusivity", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"xy diffusivity\" means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. \"biharmonic diffusivity\" means diffusivity for use with a biharmonic diffusion operator.", diff --git a/data_descriptors/standard_name/ocean_tracer_xy_laplacian_diffusivity.json b/data_descriptors/standard_name/ocean_tracer_xy_laplacian_diffusivity.json index 48cbed5dd..b2c532055 100644 --- a/data_descriptors/standard_name/ocean_tracer_xy_laplacian_diffusivity.json +++ b/data_descriptors/standard_name/ocean_tracer_xy_laplacian_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_tracer_xy_laplacian_diffusivity", + "id": "ocean_tracer_xy_laplacian_diffusivity", "type": "standard_name", "name": "ocean_tracer_xy_laplacian_diffusivity", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. \"xy diffusivity\" means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. \"laplacian diffusivity\" means diffusivity for use with a Laplacian diffusion operator.", diff --git a/data_descriptors/standard_name/ocean_vertical_diffusivity.json b/data_descriptors/standard_name/ocean_vertical_diffusivity.json index c5415216f..aea2d42ec 100644 --- a/data_descriptors/standard_name/ocean_vertical_diffusivity.json +++ b/data_descriptors/standard_name/ocean_vertical_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_diffusivity", + "id": "ocean_vertical_diffusivity", "type": "standard_name", "name": "ocean_vertical_diffusivity", "description": "\"Vertical diffusivity\" means the vertical component of diffusivity due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/ocean_vertical_heat_diffusivity.json b/data_descriptors/standard_name/ocean_vertical_heat_diffusivity.json index 42dd73964..59c0240ed 100644 --- a/data_descriptors/standard_name/ocean_vertical_heat_diffusivity.json +++ b/data_descriptors/standard_name/ocean_vertical_heat_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_heat_diffusivity", + "id": "ocean_vertical_heat_diffusivity", "type": "standard_name", "name": "ocean_vertical_heat_diffusivity", "description": "\"Vertical heat diffusivity\" means the vertical component of the diffusivity of heat due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity.json b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity.json index 2034d9600..47a9874e8 100644 --- a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity.json +++ b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_momentum_diffusivity", + "id": "ocean_vertical_momentum_diffusivity", "type": "standard_name", "name": "ocean_vertical_momentum_diffusivity", "description": "\"Vertical momentum diffusivity\" means the vertical component of the diffusivity of momentum due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_background.json b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_background.json index ee9b15f8d..24c33b581 100644 --- a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_background.json +++ b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_background.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_momentum_diffusivity_due_to_background", + "id": "ocean_vertical_momentum_diffusivity_due_to_background", "type": "standard_name", "name": "ocean_vertical_momentum_diffusivity_due_to_background", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. The construction \"vertical_X_diffusivity\" means the vertical component of the diffusivity of X due to motion which is not resolved on the grid scale of the model. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to background\" means caused by a time invariant imposed field which may be either constant over the globe or spatially varying, depending on the ocean model used.", diff --git a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_convection.json b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_convection.json index 0b82e1657..27c15ba0c 100644 --- a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_convection.json +++ b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_momentum_diffusivity_due_to_convection", + "id": "ocean_vertical_momentum_diffusivity_due_to_convection", "type": "standard_name", "name": "ocean_vertical_momentum_diffusivity_due_to_convection", "description": "\"Vertical momentum diffusivity\" means the vertical component of the diffusivity of momentum due to motion which is not resolved on the grid scale of the model. The diffusivity may be very different in the vertical and horizontal directions. Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Convective mixing in the ocean is sometimes modelled as an enhanced diffusivity.", diff --git a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_form_drag.json b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_form_drag.json index 83f893eed..43ef149b6 100644 --- a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_form_drag.json +++ b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_form_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_momentum_diffusivity_due_to_form_drag", + "id": "ocean_vertical_momentum_diffusivity_due_to_form_drag", "type": "standard_name", "name": "ocean_vertical_momentum_diffusivity_due_to_form_drag", "description": "The construction vertical_X_diffusivity means the vertical component of the diffusivity of X due to motion which is not resolved on the grid scale of the model. The diffusivity may be very different in the vertical and horizontal directions. Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to form drag\" refers to a vertical diffusivity resulting from a model scheme representing mesoscale eddy-induced form drag.", diff --git a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_tides.json b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_tides.json index 26a62fe4d..b0b4b95ef 100644 --- a/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_tides.json +++ b/data_descriptors/standard_name/ocean_vertical_momentum_diffusivity_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_momentum_diffusivity_due_to_tides", + "id": "ocean_vertical_momentum_diffusivity_due_to_tides", "type": "standard_name", "name": "ocean_vertical_momentum_diffusivity_due_to_tides", "description": "The construction vertical_X_diffusivity means the vertical component of the diffusivity of X due to motion which is not resolved on the grid scale of the model. The diffusivity may be very different in the vertical and horizontal directions. Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components.", diff --git a/data_descriptors/standard_name/ocean_vertical_salt_diffusivity.json b/data_descriptors/standard_name/ocean_vertical_salt_diffusivity.json index b4e84ca21..26de75c42 100644 --- a/data_descriptors/standard_name/ocean_vertical_salt_diffusivity.json +++ b/data_descriptors/standard_name/ocean_vertical_salt_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_salt_diffusivity", + "id": "ocean_vertical_salt_diffusivity", "type": "standard_name", "name": "ocean_vertical_salt_diffusivity", "description": "\"Vertical salt diffusivity\" means the vertical component of the diffusivity of salt due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity.json b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity.json index 4bf1e38c7..d7857bb94 100644 --- a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity.json +++ b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_tracer_diffusivity", + "id": "ocean_vertical_tracer_diffusivity", "type": "standard_name", "name": "ocean_vertical_tracer_diffusivity", "description": "\"Vertical tracer diffusivity\" means the vertical component of the diffusivity of tracers, i.e. heat and salinity, due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_background.json b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_background.json index 415ce401b..542e8bdee 100644 --- a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_background.json +++ b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_background.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_tracer_diffusivity_due_to_background", + "id": "ocean_vertical_tracer_diffusivity_due_to_background", "type": "standard_name", "name": "ocean_vertical_tracer_diffusivity_due_to_background", "description": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. The construction \"vertical_X_diffusivity\" means the vertical component of the diffusivity of X due to motion which is not resolved on the grid scale of the model. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to background\" means caused by a time invariant imposed field which may be either constant over the globe or spatially varying, depending on the ocean model used.", diff --git a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_convection.json b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_convection.json index ff682aa36..e7ad33e1e 100644 --- a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_convection.json +++ b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_tracer_diffusivity_due_to_convection", + "id": "ocean_vertical_tracer_diffusivity_due_to_convection", "type": "standard_name", "name": "ocean_vertical_tracer_diffusivity_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Vertical tracer diffusivity\" means the vertical component of the diffusivity of tracers, i.e. heat and salinity, due to motion which is not resolved on the grid scale of the model. Convective mixing in the ocean is sometimes modelled as an enhanced diffusivity.", diff --git a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_tides.json b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_tides.json index 6ac6c35ef..9b1adfd86 100644 --- a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_tides.json +++ b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_tracer_diffusivity_due_to_tides", + "id": "ocean_vertical_tracer_diffusivity_due_to_tides", "type": "standard_name", "name": "ocean_vertical_tracer_diffusivity_due_to_tides", "description": "The construction vertical_X_diffusivity means the vertical component of the diffusivity of X due to motion which is not resolved on the grid scale of the model. The diffusivity may be very different in the vertical and horizontal directions. Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components.", diff --git a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_wind_mixing.json b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_wind_mixing.json index bd1da0943..595e791b0 100644 --- a/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_wind_mixing.json +++ b/data_descriptors/standard_name/ocean_vertical_tracer_diffusivity_due_to_wind_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_vertical_tracer_diffusivity_due_to_wind_mixing", + "id": "ocean_vertical_tracer_diffusivity_due_to_wind_mixing", "type": "standard_name", "name": "ocean_vertical_tracer_diffusivity_due_to_wind_mixing", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Vertical tracer diffusivity\" means the vertical component of the diffusivity of tracers, i.e. heat and salinity, due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/ocean_volume.json b/data_descriptors/standard_name/ocean_volume.json index 89d2f1ff5..dcbde3baa 100644 --- a/data_descriptors/standard_name/ocean_volume.json +++ b/data_descriptors/standard_name/ocean_volume.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_volume", + "id": "ocean_volume", "type": "standard_name", "name": "ocean_volume", "description": null, diff --git a/data_descriptors/standard_name/ocean_volume_transport_across_line.json b/data_descriptors/standard_name/ocean_volume_transport_across_line.json index 6591d308f..a6c8951ce 100644 --- a/data_descriptors/standard_name/ocean_volume_transport_across_line.json +++ b/data_descriptors/standard_name/ocean_volume_transport_across_line.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_volume_transport_across_line", + "id": "ocean_volume_transport_across_line", "type": "standard_name", "name": "ocean_volume_transport_across_line", "description": "Transport \"across_line\" means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport.", diff --git a/data_descriptors/standard_name/ocean_volume_x_transport.json b/data_descriptors/standard_name/ocean_volume_x_transport.json index eb969b7ea..8aea2a1c2 100644 --- a/data_descriptors/standard_name/ocean_volume_x_transport.json +++ b/data_descriptors/standard_name/ocean_volume_x_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_volume_x_transport", + "id": "ocean_volume_x_transport", "type": "standard_name", "name": "ocean_volume_x_transport", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x.", diff --git a/data_descriptors/standard_name/ocean_volume_y_transport.json b/data_descriptors/standard_name/ocean_volume_y_transport.json index 4b03e9e0b..da4424511 100644 --- a/data_descriptors/standard_name/ocean_volume_y_transport.json +++ b/data_descriptors/standard_name/ocean_volume_y_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_volume_y_transport", + "id": "ocean_volume_y_transport", "type": "standard_name", "name": "ocean_volume_y_transport", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y.", diff --git a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction.json b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction.json index 1f5fc5740..261ba2509 100644 --- a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction.json +++ b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_y_overturning_mass_streamfunction", + "id": "ocean_y_overturning_mass_streamfunction", "type": "standard_name", "name": "ocean_y_overturning_mass_streamfunction", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. In contrast to the quantity with standard name ocean_meridional_overturning_streamfunction, this quantity includes all physical processes, resolved or parameterized, that impact mass/volume transport. Thus it includes contributions from the parameterized eddy velocity.", diff --git a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json index b46d1a85d..754b3a01b 100644 --- a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection", + "id": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_eddy_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json index 727ead3b3..b5a443111 100644 --- a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", + "id": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json index bee5e3668..6bdf3ea77 100644 --- a/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", + "id": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", "type": "standard_name", "name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized submesoscale eddy advection occurs on a spatial scale of the order of 1 km horizontally. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. There are also standard names for parameterized_mesoscale_eddy_advection which, along with parameterized_submesoscale_eddy_advection, contributes to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/omnidirectional_photosynthetic_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/omnidirectional_photosynthetic_spherical_irradiance_in_sea_water.json index 3f31a59e5..f157541c6 100644 --- a/data_descriptors/standard_name/omnidirectional_photosynthetic_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/omnidirectional_photosynthetic_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/omnidirectional_photosynthetic_spherical_irradiance_in_sea_water", + "id": "omnidirectional_photosynthetic_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "omnidirectional_photosynthetic_spherical_irradiance_in_sea_water", "description": "\"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Omnidirectional spherical irradiance is the radiation incident on unit area of a spherical (or \"4-pi\") collector. It is sometimes called \"scalar irradiance\". Radiation incident on a 2-pi collector has standard names of \"spherical irradiance\" which specify up/downwelling.", diff --git a/data_descriptors/standard_name/omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water.json index 20d962602..88f240685 100644 --- a/data_descriptors/standard_name/omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water", + "id": "omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "omnidirectional_spherical_irradiance_per_unit_wavelength_in_sea_water", "description": "Omnidirectional spherical irradiance is the radiation incident on unit area of a spherical (or \"4-pi\") collector. It is sometimes called \"scalar irradiance\". Radiation incident on a 2-pi collector has standard names of \"spherical irradiance\" which specify up/downwelling. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles.json index 49299754e..f80d95904 100644 --- a/data_descriptors/standard_name/optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles", + "id": "optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "optical_thickness_of_atmosphere_layer_due_to_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/original_air_pressure_of_lifted_parcel.json b/data_descriptors/standard_name/original_air_pressure_of_lifted_parcel.json index 71097ee2c..35029b8b9 100644 --- a/data_descriptors/standard_name/original_air_pressure_of_lifted_parcel.json +++ b/data_descriptors/standard_name/original_air_pressure_of_lifted_parcel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/original_air_pressure_of_lifted_parcel", + "id": "original_air_pressure_of_lifted_parcel", "type": "standard_name", "name": "original_air_pressure_of_lifted_parcel", "description": "Various stability and convective potential indices are calculated by \"lifting\" a parcel of air: moving it dry adiabatically from a starting height (often the surface) to the Lifting Condensation Level, and then wet adiabatically from there to an ending height (often the top of the data/model/atmosphere). The quantities with standard names original_air_pressure_of_lifted_parcel and final_air_pressure_of_lifted_parcel are the ambient air pressure at the start and end of lifting, respectively. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/outgoing_water_volume_transport_along_river_channel.json b/data_descriptors/standard_name/outgoing_water_volume_transport_along_river_channel.json index bee75ad46..6c5f62f1c 100644 --- a/data_descriptors/standard_name/outgoing_water_volume_transport_along_river_channel.json +++ b/data_descriptors/standard_name/outgoing_water_volume_transport_along_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/outgoing_water_volume_transport_along_river_channel", + "id": "outgoing_water_volume_transport_along_river_channel", "type": "standard_name", "name": "outgoing_water_volume_transport_along_river_channel", "description": "\"Water\" means water in all phases. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/partial_pressure_of_carbon_dioxide_in_sea_water.json b/data_descriptors/standard_name/partial_pressure_of_carbon_dioxide_in_sea_water.json index ba8c87e0e..0c7f9bacc 100644 --- a/data_descriptors/standard_name/partial_pressure_of_carbon_dioxide_in_sea_water.json +++ b/data_descriptors/standard_name/partial_pressure_of_carbon_dioxide_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/partial_pressure_of_carbon_dioxide_in_sea_water", + "id": "partial_pressure_of_carbon_dioxide_in_sea_water", "type": "standard_name", "name": "partial_pressure_of_carbon_dioxide_in_sea_water", "description": "The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/partial_pressure_of_methane_in_sea_water.json b/data_descriptors/standard_name/partial_pressure_of_methane_in_sea_water.json index 0348f7900..67bf941c1 100644 --- a/data_descriptors/standard_name/partial_pressure_of_methane_in_sea_water.json +++ b/data_descriptors/standard_name/partial_pressure_of_methane_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/partial_pressure_of_methane_in_sea_water", + "id": "partial_pressure_of_methane_in_sea_water", "type": "standard_name", "name": "partial_pressure_of_methane_in_sea_water", "description": "The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/perceived_temperature.json b/data_descriptors/standard_name/perceived_temperature.json index fe43fa87d..850e6aa31 100644 --- a/data_descriptors/standard_name/perceived_temperature.json +++ b/data_descriptors/standard_name/perceived_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/perceived_temperature", + "id": "perceived_temperature", "type": "standard_name", "name": "perceived_temperature", "description": "Perceived temperature (PT) is an equivalent air temperature of the actual thermal condition. It is the air temperature of a reference condition causing the same thermal perception in a human body considering air temperature, wind speed, humidity, solar and thermal radiation as well as clothing and activity level. It is not the perceived air temperature, that derives either from wind chill and heat index and has the standard_name apparent_air_temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/permafrost_active_layer_thickness.json b/data_descriptors/standard_name/permafrost_active_layer_thickness.json index 5da2fa1ee..1f9962bf3 100644 --- a/data_descriptors/standard_name/permafrost_active_layer_thickness.json +++ b/data_descriptors/standard_name/permafrost_active_layer_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/permafrost_active_layer_thickness", + "id": "permafrost_active_layer_thickness", "type": "standard_name", "name": "permafrost_active_layer_thickness", "description": "The quantity with standard name permafrost_active_layer_thickness is the thickness of the layer of the ground that is subject to annual thawing and freezing in areas underlain by permafrost. \"Thickness\" means the vertical extent of a layer. Permafrost is soil or rock that has remained at a temperature at or below zero degrees Celsius throughout the seasonal cycle for two or more years.", diff --git a/data_descriptors/standard_name/permafrost_area_fraction.json b/data_descriptors/standard_name/permafrost_area_fraction.json index b8f15b907..e248db0bf 100644 --- a/data_descriptors/standard_name/permafrost_area_fraction.json +++ b/data_descriptors/standard_name/permafrost_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/permafrost_area_fraction", + "id": "permafrost_area_fraction", "type": "standard_name", "name": "permafrost_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Permafrost is soil or rock that has remained at a temperature at or below zero degrees Celsius throughout the seasonal cycle for two or more years.", diff --git a/data_descriptors/standard_name/permafrost_layer_thickness.json b/data_descriptors/standard_name/permafrost_layer_thickness.json index c6e13ef4d..794293f40 100644 --- a/data_descriptors/standard_name/permafrost_layer_thickness.json +++ b/data_descriptors/standard_name/permafrost_layer_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/permafrost_layer_thickness", + "id": "permafrost_layer_thickness", "type": "standard_name", "name": "permafrost_layer_thickness", "description": "Permafrost is soil or rock that has remained at a temperature at or below zero degrees Celsius throughout the seasonal cycle for two or more years. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/phase_of_global_average_sea_level_change.json b/data_descriptors/standard_name/phase_of_global_average_sea_level_change.json index 9dff953d2..78de1da94 100644 --- a/data_descriptors/standard_name/phase_of_global_average_sea_level_change.json +++ b/data_descriptors/standard_name/phase_of_global_average_sea_level_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/phase_of_global_average_sea_level_change", + "id": "phase_of_global_average_sea_level_change", "type": "standard_name", "name": "phase_of_global_average_sea_level_change", "description": "Global average sea level change is due to change in volume of the water in the ocean, caused by mass and/or density change, or to change in the volume of the ocean basins, caused by tectonics etc. It is sometimes called \"eustatic\", which is a term that also has other definitions. It differs from the change in the global average sea surface height relative to the centre of the Earth by the global average vertical movement of the ocean floor. Zero sea level change is an arbitrary level. Phase is the initial angle of a wave modelled by a sinusoidal function. A coordinate variable of harmonic_period should be used to specify the period of the sinusoidal wave. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level.", diff --git a/data_descriptors/standard_name/phosphorus_mass_transport_in_river_channel.json b/data_descriptors/standard_name/phosphorus_mass_transport_in_river_channel.json index c758689f2..72366e95e 100644 --- a/data_descriptors/standard_name/phosphorus_mass_transport_in_river_channel.json +++ b/data_descriptors/standard_name/phosphorus_mass_transport_in_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/phosphorus_mass_transport_in_river_channel", + "id": "phosphorus_mass_transport_in_river_channel", "type": "standard_name", "name": "phosphorus_mass_transport_in_river_channel", "description": "The amount of total phosphorus mass transported in the river channels from land into the ocean. This quantity can be provided at a certain location within the river network and floodplain (over land) or at the river mouth (over ocean) where the river enters the ocean. \"River\" refers to water in the fluvial system (stream and floodplain). Phosphorus means phosphorus in all chemical forms, commonly referred to as \"total phosphorus\".", diff --git a/data_descriptors/standard_name/photolysis_rate_of_molecular_oxygen.json b/data_descriptors/standard_name/photolysis_rate_of_molecular_oxygen.json index 62fea973d..5267a40c6 100644 --- a/data_descriptors/standard_name/photolysis_rate_of_molecular_oxygen.json +++ b/data_descriptors/standard_name/photolysis_rate_of_molecular_oxygen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/photolysis_rate_of_molecular_oxygen", + "id": "photolysis_rate_of_molecular_oxygen", "type": "standard_name", "name": "photolysis_rate_of_molecular_oxygen", "description": "\"Photolysis\" is a chemical reaction in which a chemical compound is broken down by photons. The \"reaction rate\" is the rate at which the reactants of a chemical reaction form the products. The chemical formula for molecular oxygen is O2.", diff --git a/data_descriptors/standard_name/photolysis_rate_of_nitrogen_dioxide.json b/data_descriptors/standard_name/photolysis_rate_of_nitrogen_dioxide.json index f92fbf100..14a85ced1 100644 --- a/data_descriptors/standard_name/photolysis_rate_of_nitrogen_dioxide.json +++ b/data_descriptors/standard_name/photolysis_rate_of_nitrogen_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/photolysis_rate_of_nitrogen_dioxide", + "id": "photolysis_rate_of_nitrogen_dioxide", "type": "standard_name", "name": "photolysis_rate_of_nitrogen_dioxide", "description": "\"Photolysis\" is a chemical reaction in which a chemical compound is broken down by photons. The \"reaction rate\" is the rate at which the reactants of a chemical reaction form the products. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/photolysis_rate_of_ozone.json b/data_descriptors/standard_name/photolysis_rate_of_ozone.json index ed93d166c..673aa0dfe 100644 --- a/data_descriptors/standard_name/photolysis_rate_of_ozone.json +++ b/data_descriptors/standard_name/photolysis_rate_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/photolysis_rate_of_ozone", + "id": "photolysis_rate_of_ozone", "type": "standard_name", "name": "photolysis_rate_of_ozone", "description": "\"Photolysis\" is a chemical reaction in which a chemical compound is broken down by photons. The \"reaction rate\" is the rate at which the reactants of a chemical reaction form the products. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen. The quantity with standard name photolysis_rate_of_ozone is the rate of photolytic loss of ozone, including all possible photolysis channels to form ground state atomic oxygen (O3P ) and excited (singlet D) atomic oxygen (O1D). Photolysis to the excited state only has the standard name photolysis_rate_of_ozone_to_1D_oxygen_atom.", diff --git a/data_descriptors/standard_name/photolysis_rate_of_ozone_to_1D_oxygen_atom.json b/data_descriptors/standard_name/photolysis_rate_of_ozone_to_1D_oxygen_atom.json index cc629e6df..4085e9f3b 100644 --- a/data_descriptors/standard_name/photolysis_rate_of_ozone_to_1D_oxygen_atom.json +++ b/data_descriptors/standard_name/photolysis_rate_of_ozone_to_1D_oxygen_atom.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/photolysis_rate_of_ozone_to_1D_oxygen_atom", + "id": "photolysis_rate_of_ozone_to_1D_oxygen_atom", "type": "standard_name", "name": "photolysis_rate_of_ozone_to_1D_oxygen_atom", "description": "\"Photolysis\" is a chemical reaction in which a chemical compound is broken down by photons. The \"reaction rate\" is the rate at which the reactants of a chemical reaction form the products. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen. \"1D oxygen atom\" means the singlet D state, an excited state, of the oxygen atom. The combined photolysis rate of ozone to both excited and ground state oxygen atoms has the standard name photolysis_rate_of_ozone.", diff --git a/data_descriptors/standard_name/physiological_equivalent_temperature.json b/data_descriptors/standard_name/physiological_equivalent_temperature.json index 53a7710e9..a311822f1 100644 --- a/data_descriptors/standard_name/physiological_equivalent_temperature.json +++ b/data_descriptors/standard_name/physiological_equivalent_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/physiological_equivalent_temperature", + "id": "physiological_equivalent_temperature", "type": "standard_name", "name": "physiological_equivalent_temperature", "description": "Physiological equivalent temperature (PET) is an equivalent air temperature of the actual thermal condition. It is the air temperature of a reference condition without wind and solar radiation at which the heat budget of the human body is balanced with the same core and skin temperature. Note that PET here is not potential evapotranspiration. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/planetary_albedo.json b/data_descriptors/standard_name/planetary_albedo.json index 655a642d0..8206ebce7 100644 --- a/data_descriptors/standard_name/planetary_albedo.json +++ b/data_descriptors/standard_name/planetary_albedo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/planetary_albedo", + "id": "planetary_albedo", "type": "standard_name", "name": "planetary_albedo", "description": "Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum.", diff --git a/data_descriptors/standard_name/platform_azimuth_angle.json b/data_descriptors/standard_name/platform_azimuth_angle.json index ccb02f903..8ddfb2f4f 100644 --- a/data_descriptors/standard_name/platform_azimuth_angle.json +++ b/data_descriptors/standard_name/platform_azimuth_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_azimuth_angle", + "id": "platform_azimuth_angle", "type": "standard_name", "name": "platform_azimuth_angle", "description": "Platform azimuth angle is the horizontal angle between the line of sight from the observation point to the platform and a reference direction at the observation point, which is often due north. The angle is measured clockwise positive, starting from the reference direction. A comment attribute should be added to a data variable with the standard name platform_azimuth_angle to specify the reference direction. A standard name also exists for sensor_azimuth_angle. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated azimuth angle. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_course.json b/data_descriptors/standard_name/platform_course.json index de3e3885f..c59890bd5 100644 --- a/data_descriptors/standard_name/platform_course.json +++ b/data_descriptors/standard_name/platform_course.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_course", + "id": "platform_course", "type": "standard_name", "name": "platform_course", "description": "Course is the clockwise angle with respect to North of the nominal forward motion direction of the platform (not necessarily the same as the direction in which it is pointing, called \"platform_orientation\"). A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_heave.json b/data_descriptors/standard_name/platform_heave.json index f1e10e8bf..56a34c282 100644 --- a/data_descriptors/standard_name/platform_heave.json +++ b/data_descriptors/standard_name/platform_heave.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_heave", + "id": "platform_heave", "type": "standard_name", "name": "platform_heave", "description": "Heave is a displacement along the local vertical axis. Heave is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. The standard name platform_heave should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the heave is known, a standard name of platform_heave_down or platform_heave_up should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_heave_down.json b/data_descriptors/standard_name/platform_heave_down.json index 32cb87043..18935d1d2 100644 --- a/data_descriptors/standard_name/platform_heave_down.json +++ b/data_descriptors/standard_name/platform_heave_down.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_heave_down", + "id": "platform_heave_down", "type": "standard_name", "name": "platform_heave_down", "description": "Heave is a displacement along the local vertical axis. Heave is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. \"Down\" indicates that positive values of heave represent the platform moving down as viewed by an observer on top of the platform facing forward. The standard name platform_heave_up should be used for data having the opposite sign convention. The standard name platform_heave should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_heave_rate.json b/data_descriptors/standard_name/platform_heave_rate.json index da6251dcd..888a256c2 100644 --- a/data_descriptors/standard_name/platform_heave_rate.json +++ b/data_descriptors/standard_name/platform_heave_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_heave_rate", + "id": "platform_heave_rate", "type": "standard_name", "name": "platform_heave_rate", "description": "\"Heave rate\" is the rate of displacement along the local vertical axis. Heave rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. The standard name platform_heave_rate should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the heave rate is known, a standard name of platform_heave_rate_down or platform_heave_rate_up should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_heave_rate_down.json b/data_descriptors/standard_name/platform_heave_rate_down.json index 69abadd2d..ab152915f 100644 --- a/data_descriptors/standard_name/platform_heave_rate_down.json +++ b/data_descriptors/standard_name/platform_heave_rate_down.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_heave_rate_down", + "id": "platform_heave_rate_down", "type": "standard_name", "name": "platform_heave_rate_down", "description": "\"Heave rate\" is the rate of displacement along the local vertical axis. Heave rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. \"Down\" indicates that positive values of heave rate represent the platform moving down as viewed by an observer on top of the platform facing forward. The standard name platform_heave_rate_up should be used for data having the opposite sign convention. The standard name platform_heave_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_heave_rate_up.json b/data_descriptors/standard_name/platform_heave_rate_up.json index 54ff33463..af8ed9a08 100644 --- a/data_descriptors/standard_name/platform_heave_rate_up.json +++ b/data_descriptors/standard_name/platform_heave_rate_up.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_heave_rate_up", + "id": "platform_heave_rate_up", "type": "standard_name", "name": "platform_heave_rate_up", "description": "\"Heave rate\" is the rate of displacement along the local vertical axis. Heave rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. \"Up\" indicates that positive values of heave rate represent the platform moving up as viewed by an observer on top of the platform facing forward. The standard name platform_heave_rate_down should be used for data having the opposite sign convention. The standard name platform_heave_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_heave_up.json b/data_descriptors/standard_name/platform_heave_up.json index 2f494d695..6e1ba6388 100644 --- a/data_descriptors/standard_name/platform_heave_up.json +++ b/data_descriptors/standard_name/platform_heave_up.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_heave_up", + "id": "platform_heave_up", "type": "standard_name", "name": "platform_heave_up", "description": "Heave is a displacement along the local vertical axis. Heave is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. \"Up\" indicates that positive values of heave represent the platform moving up as viewed by an observer on top of the platform facing forward. The standard name platform_heave_down should be used for data having the opposite sign convention. The standard name platform_heave should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_id.json b/data_descriptors/standard_name/platform_id.json index fa4080705..c154f824d 100644 --- a/data_descriptors/standard_name/platform_id.json +++ b/data_descriptors/standard_name/platform_id.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_id", + "id": "platform_id", "type": "standard_name", "name": "platform_id", "description": "A variable with the standard name of platform_id contains strings which help to identify the platform from which an observation was made. For example, this may be a WMO station identification number. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_name.json b/data_descriptors/standard_name/platform_name.json index c1ee2f632..d2cdf79c0 100644 --- a/data_descriptors/standard_name/platform_name.json +++ b/data_descriptors/standard_name/platform_name.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_name", + "id": "platform_name", "type": "standard_name", "name": "platform_name", "description": "A variable with the standard name of platform_name contains strings which help to identify the platform from which an observation was made. For example, this may be a geographical place name such as \"South Pole\" or the name of a meteorological observing station. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_orientation.json b/data_descriptors/standard_name/platform_orientation.json index aeecc61b4..d24e410ab 100644 --- a/data_descriptors/standard_name/platform_orientation.json +++ b/data_descriptors/standard_name/platform_orientation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_orientation", + "id": "platform_orientation", "type": "standard_name", "name": "platform_orientation", "description": "Orientation is the clockwise angle with respect to North of the longitudinal (front-to-back) axis of the platform, which may be different to the platform course (which has the standard name platform_course). A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_pitch.json b/data_descriptors/standard_name/platform_pitch.json index cd174999e..22d5f75a9 100644 --- a/data_descriptors/standard_name/platform_pitch.json +++ b/data_descriptors/standard_name/platform_pitch.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_pitch", + "id": "platform_pitch", "type": "standard_name", "name": "platform_pitch", "description": "Pitch is a rotation about an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Pitch is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. The standard name platform_pitch should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the pitch is known, a standard name of platform_pitch_fore_down or platform_pitch_fore_up should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_pitch_fore_down.json b/data_descriptors/standard_name/platform_pitch_fore_down.json index 9e5beae29..eef6c5194 100644 --- a/data_descriptors/standard_name/platform_pitch_fore_down.json +++ b/data_descriptors/standard_name/platform_pitch_fore_down.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_pitch_fore_down", + "id": "platform_pitch_fore_down", "type": "standard_name", "name": "platform_pitch_fore_down", "description": "Pitch is a rotation about an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Pitch is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. \"Fore down\" indicates that positive values of pitch represent the front of the platform falling as viewed by an observer on top of the platform facing forward. The standard name platform_pitch_fore_up should be used for data having the opposite sign convention. The standard name platform_pitch should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_pitch_fore_up.json b/data_descriptors/standard_name/platform_pitch_fore_up.json index 90e0ec794..feef8f209 100644 --- a/data_descriptors/standard_name/platform_pitch_fore_up.json +++ b/data_descriptors/standard_name/platform_pitch_fore_up.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_pitch_fore_up", + "id": "platform_pitch_fore_up", "type": "standard_name", "name": "platform_pitch_fore_up", "description": "Pitch is a rotation about an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Pitch is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. \"Fore up\" indicates that positive values of pitch represent the front of the platform rising as viewed by an observer on top of the platform facing forward. The standard name platform_pitch_fore_down should be used for data having the opposite sign convention. The standard name platform_pitch should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_pitch_rate.json b/data_descriptors/standard_name/platform_pitch_rate.json index c775dced5..6d66c55de 100644 --- a/data_descriptors/standard_name/platform_pitch_rate.json +++ b/data_descriptors/standard_name/platform_pitch_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_pitch_rate", + "id": "platform_pitch_rate", "type": "standard_name", "name": "platform_pitch_rate", "description": "\"Pitch rate\" is the rate of rotation about an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Pitch rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. The standard name platform_pitch_rate should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the pitch rate is known, a standard name of platform_pitch_rate_fore_down or platform_pitch_rate_fore_up should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_pitch_rate_fore_down.json b/data_descriptors/standard_name/platform_pitch_rate_fore_down.json index 02b843ccc..5dc209bde 100644 --- a/data_descriptors/standard_name/platform_pitch_rate_fore_down.json +++ b/data_descriptors/standard_name/platform_pitch_rate_fore_down.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_pitch_rate_fore_down", + "id": "platform_pitch_rate_fore_down", "type": "standard_name", "name": "platform_pitch_rate_fore_down", "description": "\"Pitch rate\" is the rate of rotation about an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Pitch rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. \"Fore down\" indicates that positive values of pitch rate represent the front of the platform falling as viewed by an observer on top of the platform facing forward. The standard name platform_pitch_rate_fore_up should be used for data having the opposite sign convention. The standard name platform_pitch_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_pitch_rate_fore_up.json b/data_descriptors/standard_name/platform_pitch_rate_fore_up.json index 89e9aaef2..4e8aa1c57 100644 --- a/data_descriptors/standard_name/platform_pitch_rate_fore_up.json +++ b/data_descriptors/standard_name/platform_pitch_rate_fore_up.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_pitch_rate_fore_up", + "id": "platform_pitch_rate_fore_up", "type": "standard_name", "name": "platform_pitch_rate_fore_up", "description": "\"Pitch rate\" is the rate of rotation about an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Pitch rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. \"Fore up\" indicates that positive values of pitch rate represent the front of the platform rising as viewed by an observer on top of the platform facing forward. The standard name platform_pitch_rate_fore_down should be used for data having the opposite sign convention. The standard name platform_pitch_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_roll.json b/data_descriptors/standard_name/platform_roll.json index 79ab04e75..dfc0ed60b 100644 --- a/data_descriptors/standard_name/platform_roll.json +++ b/data_descriptors/standard_name/platform_roll.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_roll", + "id": "platform_roll", "type": "standard_name", "name": "platform_roll", "description": "Roll is a rotation about an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Roll is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. The standard name platform_roll should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the roll is known, a standard name of platform_roll_starboard_down or platform_roll_starboard_up should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_roll_rate.json b/data_descriptors/standard_name/platform_roll_rate.json index 679c28bbf..4446401c5 100644 --- a/data_descriptors/standard_name/platform_roll_rate.json +++ b/data_descriptors/standard_name/platform_roll_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_roll_rate", + "id": "platform_roll_rate", "type": "standard_name", "name": "platform_roll_rate", "description": "\"Roll rate\" is the rate of rotation about an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Roll rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. The standard name platform_roll_rate should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the roll rate is known, a standard name of platform_roll_rate_starboard_down or platform_roll_rate_starboard_up should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_roll_rate_starboard_down.json b/data_descriptors/standard_name/platform_roll_rate_starboard_down.json index 8f5112f20..04d1f5efc 100644 --- a/data_descriptors/standard_name/platform_roll_rate_starboard_down.json +++ b/data_descriptors/standard_name/platform_roll_rate_starboard_down.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_roll_rate_starboard_down", + "id": "platform_roll_rate_starboard_down", "type": "standard_name", "name": "platform_roll_rate_starboard_down", "description": "\"Roll rate\" is the rate of rotation about an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Roll rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. \"Starboard down\" indicates that positive values of roll rate represent the right side of the platform falling as viewed by an observer on top of the platform facing forward. The standard name platform_roll_rate_starboard_up should be used for data having the opposite sign convention. The standard name platform_roll_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_roll_rate_starboard_up.json b/data_descriptors/standard_name/platform_roll_rate_starboard_up.json index 5f2620455..7e2ac13d9 100644 --- a/data_descriptors/standard_name/platform_roll_rate_starboard_up.json +++ b/data_descriptors/standard_name/platform_roll_rate_starboard_up.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_roll_rate_starboard_up", + "id": "platform_roll_rate_starboard_up", "type": "standard_name", "name": "platform_roll_rate_starboard_up", "description": "\"Roll rate\" is the rate of rotation about an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Roll rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. \"Starboard up\" indicates that positive values of roll rate represent the right side of the platform rising as viewed by an observer on top of the platform facing forward. The standard name platform_roll_rate_starboard_down should be used for data having the opposite sign convention. The standard name platform_roll_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_roll_starboard_down.json b/data_descriptors/standard_name/platform_roll_starboard_down.json index bc8630918..625cc8f15 100644 --- a/data_descriptors/standard_name/platform_roll_starboard_down.json +++ b/data_descriptors/standard_name/platform_roll_starboard_down.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_roll_starboard_down", + "id": "platform_roll_starboard_down", "type": "standard_name", "name": "platform_roll_starboard_down", "description": "Roll is a rotation about an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Roll is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. \"Starboard down\" indicates that positive values of roll represent the right side of the platform falling as viewed by an observer on top of the platform facing forward. The standard name platform_roll_starboard_up should be used for data having the opposite sign convention. The standard name platform_roll should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_roll_starboard_up.json b/data_descriptors/standard_name/platform_roll_starboard_up.json index f04f20815..4c82f48cc 100644 --- a/data_descriptors/standard_name/platform_roll_starboard_up.json +++ b/data_descriptors/standard_name/platform_roll_starboard_up.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_roll_starboard_up", + "id": "platform_roll_starboard_up", "type": "standard_name", "name": "platform_roll_starboard_up", "description": "Roll is a rotation about an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Roll is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. \"Starboard up\" indicates that positive values of roll represent the right side of the platform rising as viewed by an observer on top of the platform facing forward. The standard name platform_roll_starboard_down should be used for data having the opposite sign convention. The standard name platform_roll should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_speed_wrt_air.json b/data_descriptors/standard_name/platform_speed_wrt_air.json index 19e6fc358..d405a84c9 100644 --- a/data_descriptors/standard_name/platform_speed_wrt_air.json +++ b/data_descriptors/standard_name/platform_speed_wrt_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_speed_wrt_air", + "id": "platform_speed_wrt_air", "type": "standard_name", "name": "platform_speed_wrt_air", "description": "Speed is the magnitude of velocity. The abbreviation \"wrt\" means with respect to. The platform speed with respect to air is often called the \"air speed\" of the platform. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_speed_wrt_ground.json b/data_descriptors/standard_name/platform_speed_wrt_ground.json index 2ed807112..8234cbc27 100644 --- a/data_descriptors/standard_name/platform_speed_wrt_ground.json +++ b/data_descriptors/standard_name/platform_speed_wrt_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_speed_wrt_ground", + "id": "platform_speed_wrt_ground", "type": "standard_name", "name": "platform_speed_wrt_ground", "description": "Speed is the magnitude of velocity. The abbreviation \"wrt\" means with respect to. The platform speed with respect to ground is relative to the solid Earth beneath it, i.e. the sea floor for a ship. It is often called the \"ground speed\" of the platform. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_speed_wrt_sea_water.json b/data_descriptors/standard_name/platform_speed_wrt_sea_water.json index b79f4f768..b540f2fc2 100644 --- a/data_descriptors/standard_name/platform_speed_wrt_sea_water.json +++ b/data_descriptors/standard_name/platform_speed_wrt_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_speed_wrt_sea_water", + "id": "platform_speed_wrt_sea_water", "type": "standard_name", "name": "platform_speed_wrt_sea_water", "description": "Speed is the magnitude of velocity. The abbreviation \"wrt\" means with respect to. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_surge.json b/data_descriptors/standard_name/platform_surge.json index 3cbe053dc..101fba0b1 100644 --- a/data_descriptors/standard_name/platform_surge.json +++ b/data_descriptors/standard_name/platform_surge.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_surge", + "id": "platform_surge", "type": "standard_name", "name": "platform_surge", "description": "Surge is a displacement along an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Surge is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. The standard name platform_surge should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the surge is known, a standard name of platform_surge_fore or platform_surge_aft should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_surge_aft.json b/data_descriptors/standard_name/platform_surge_aft.json index 010cc2e0a..11b67bb20 100644 --- a/data_descriptors/standard_name/platform_surge_aft.json +++ b/data_descriptors/standard_name/platform_surge_aft.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_surge_aft", + "id": "platform_surge_aft", "type": "standard_name", "name": "platform_surge_aft", "description": "Surge is a displacement along an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Surge is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. \"Aft\" indicates that positive values of surge represent the platform moving backward as viewed by an observer on top of the platform facing forward. The standard name platform_surge_fore should be used for data having the opposite sign convention. The standard name platform_surge should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_surge_fore.json b/data_descriptors/standard_name/platform_surge_fore.json index 46e3eb023..b3b58d052 100644 --- a/data_descriptors/standard_name/platform_surge_fore.json +++ b/data_descriptors/standard_name/platform_surge_fore.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_surge_fore", + "id": "platform_surge_fore", "type": "standard_name", "name": "platform_surge_fore", "description": "Surge is a displacement along an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Surge is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. \"Fore\" indicates that positive values of surge represent the platform moving forward as viewed by an observer on top of the platform facing forward. The standard name platform_surge_aft should be used for data having the opposite sign convention. The standard name platform_surge should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_surge_rate.json b/data_descriptors/standard_name/platform_surge_rate.json index 6bd35b93e..c69f69fc5 100644 --- a/data_descriptors/standard_name/platform_surge_rate.json +++ b/data_descriptors/standard_name/platform_surge_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_surge_rate", + "id": "platform_surge_rate", "type": "standard_name", "name": "platform_surge_rate", "description": "\"Surge rate\" is the rate of displacement along an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Surge rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. The standard name platform_surge_rate should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the surge rate is known, a standard name of platform_surge_rate_fore or platform_surge_rate_aft should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_surge_rate_aft.json b/data_descriptors/standard_name/platform_surge_rate_aft.json index ce0a161a7..6411a21a4 100644 --- a/data_descriptors/standard_name/platform_surge_rate_aft.json +++ b/data_descriptors/standard_name/platform_surge_rate_aft.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_surge_rate_aft", + "id": "platform_surge_rate_aft", "type": "standard_name", "name": "platform_surge_rate_aft", "description": "\"Surge rate\" is the rate of displacement along an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Surge rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. \"Aft\" indicates that positive values of surge rate represent the platform moving backward as viewed by an observer on top of the platform facing forward. The standard name platform_surge_rate_fore should be used for data having the opposite sign convention. The standard name platform_surge_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_surge_rate_fore.json b/data_descriptors/standard_name/platform_surge_rate_fore.json index 266fa95f6..05ea203f3 100644 --- a/data_descriptors/standard_name/platform_surge_rate_fore.json +++ b/data_descriptors/standard_name/platform_surge_rate_fore.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_surge_rate_fore", + "id": "platform_surge_rate_fore", "type": "standard_name", "name": "platform_surge_rate_fore", "description": "\"Surge rate\" is the rate of displacement along an axis that is perpendicular to the local vertical axis and is coplanar with the nominal forward motion direction of the platform. Surge rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. \"Fore\" indicates that positive values of surge rate represent the platform moving forward as viewed by an observer on top of the platform facing forward. The standard name platform_surge_rate_aft should be used for data having the opposite sign convention. The standard name platform_surge_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_sway.json b/data_descriptors/standard_name/platform_sway.json index c7be8675a..67501628b 100644 --- a/data_descriptors/standard_name/platform_sway.json +++ b/data_descriptors/standard_name/platform_sway.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_sway", + "id": "platform_sway", "type": "standard_name", "name": "platform_sway", "description": "Sway is a displacement along an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Sway is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. The standard name platform_sway should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the sway is known, a standard name of platform_sway_starboard or platform_sway_port should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_sway_port.json b/data_descriptors/standard_name/platform_sway_port.json index e41b8128d..7163aa322 100644 --- a/data_descriptors/standard_name/platform_sway_port.json +++ b/data_descriptors/standard_name/platform_sway_port.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_sway_port", + "id": "platform_sway_port", "type": "standard_name", "name": "platform_sway_port", "description": "Sway is a displacement along an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Sway is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. \"Port\" indicates that positive values of sway represent the platform moving left as viewed by an observer on top of the platform facing forward. The standard name platform_sway_starboard should be used for data having the opposite sign convention. The standard name platform_sway should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_sway_rate.json b/data_descriptors/standard_name/platform_sway_rate.json index d44ba647e..fd50f53a8 100644 --- a/data_descriptors/standard_name/platform_sway_rate.json +++ b/data_descriptors/standard_name/platform_sway_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_sway_rate", + "id": "platform_sway_rate", "type": "standard_name", "name": "platform_sway_rate", "description": "\"Sway rate\" is the rate of displacement along an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Sway rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. The standard name platform_sway_rate should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the sway rate is known, a standard name of platform_sway_rate_starboard or platform_sway_rate_port should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_sway_rate_port.json b/data_descriptors/standard_name/platform_sway_rate_port.json index 77b370b7d..587fd92f7 100644 --- a/data_descriptors/standard_name/platform_sway_rate_port.json +++ b/data_descriptors/standard_name/platform_sway_rate_port.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_sway_rate_port", + "id": "platform_sway_rate_port", "type": "standard_name", "name": "platform_sway_rate_port", "description": "\"Sway rate\" is the rate of displacement along an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Sway rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. \"Port\" indicates that positive values of sway rate represent the platform moving left as viewed by an observer on top of the platform facing forward. The standard name platform_sway_rate_starboard should be used for data having the opposite sign convention. The standard name platform_sway_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_sway_rate_starboard.json b/data_descriptors/standard_name/platform_sway_rate_starboard.json index 7e618d2cb..f88590e60 100644 --- a/data_descriptors/standard_name/platform_sway_rate_starboard.json +++ b/data_descriptors/standard_name/platform_sway_rate_starboard.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_sway_rate_starboard", + "id": "platform_sway_rate_starboard", "type": "standard_name", "name": "platform_sway_rate_starboard", "description": "\"Sway rate\" is the rate of displacement along an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Sway rate might not include changes to the \"at rest\" position of the platform with respect to the axis of displacement, which may change over time. \"Starboard\" indicates that positive values of sway rate represent the platform moving right as viewed by an observer on top of the platform facing forward. The standard name platform_sway_rate_port should be used for data having the opposite sign convention. The standard name platform_sway_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_sway_starboard.json b/data_descriptors/standard_name/platform_sway_starboard.json index ebc7b5320..63b1c4369 100644 --- a/data_descriptors/standard_name/platform_sway_starboard.json +++ b/data_descriptors/standard_name/platform_sway_starboard.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_sway_starboard", + "id": "platform_sway_starboard", "type": "standard_name", "name": "platform_sway_starboard", "description": "Sway is a displacement along an axis that is perpendicular to both the local vertical axis and the nominal forward motion direction of the platform. Sway is relative to the \"at rest\" position of the platform with respect to the axis of displacement. The \"at rest\" position of the platform may change over time. \"Starboard\" indicates that positive values of sway represent the platform moving right as viewed by an observer on top of the platform facing forward. The standard name platform_sway_port should be used for data having the opposite sign convention. The standard name platform_sway should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_view_angle.json b/data_descriptors/standard_name/platform_view_angle.json index 82cbb336b..7dbc34181 100644 --- a/data_descriptors/standard_name/platform_view_angle.json +++ b/data_descriptors/standard_name/platform_view_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_view_angle", + "id": "platform_view_angle", "type": "standard_name", "name": "platform_view_angle", "description": "Platform view angle is the angle between the line of sight from the platform and the direction straight vertically down. Zero view angle means looking directly beneath the platform. There is no standardized sign convention for platform_view_angle. A standard name also exists for sensor_view_angle. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated view angle. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_yaw.json b/data_descriptors/standard_name/platform_yaw.json index 9ebf9cc84..1a0f29b08 100644 --- a/data_descriptors/standard_name/platform_yaw.json +++ b/data_descriptors/standard_name/platform_yaw.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_yaw", + "id": "platform_yaw", "type": "standard_name", "name": "platform_yaw", "description": "Yaw is a rotation about the local vertical axis. Yaw is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. The standard name platform_yaw should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the yaw is known, a standard name of platform_yaw_fore_starboard or platform_yaw_fore_port should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_yaw_fore_port.json b/data_descriptors/standard_name/platform_yaw_fore_port.json index ae4ebec99..063f9e29a 100644 --- a/data_descriptors/standard_name/platform_yaw_fore_port.json +++ b/data_descriptors/standard_name/platform_yaw_fore_port.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_yaw_fore_port", + "id": "platform_yaw_fore_port", "type": "standard_name", "name": "platform_yaw_fore_port", "description": "Yaw is a rotation about the local vertical axis. Yaw is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. \"Fore port\" indicates that positive values of yaw represent the front of the platform moving to the left as viewed by an observer on top of the platform facing forward. The standard name platform_yaw_fore_starboard should be used for data having the opposite sign convention. The standard name platform_yaw should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_yaw_fore_starboard.json b/data_descriptors/standard_name/platform_yaw_fore_starboard.json index b52a07def..46e5f82cf 100644 --- a/data_descriptors/standard_name/platform_yaw_fore_starboard.json +++ b/data_descriptors/standard_name/platform_yaw_fore_starboard.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_yaw_fore_starboard", + "id": "platform_yaw_fore_starboard", "type": "standard_name", "name": "platform_yaw_fore_starboard", "description": "Yaw is a rotation about the local vertical axis. Yaw is relative to the \"at rest\" rotation of the platform with respect to the axis of rotation. The \"at rest\" rotation of the platform may change over time. \"Fore starboard\" indicates that positive values of yaw represent the front of the platform moving to the right as viewed by an observer on top of the platform facing forward. The standard name platform_yaw_fore_port should be used for data having the opposite sign convention. The standard name platform_yaw should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_yaw_rate.json b/data_descriptors/standard_name/platform_yaw_rate.json index 1d33f093c..fb0f52b88 100644 --- a/data_descriptors/standard_name/platform_yaw_rate.json +++ b/data_descriptors/standard_name/platform_yaw_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_yaw_rate", + "id": "platform_yaw_rate", "type": "standard_name", "name": "platform_yaw_rate", "description": "\"Yaw rate\" is the rate of rotation about the local vertical axis. Yaw rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. The standard name platform_yaw_rate should be chosen only if the sign convention of the data is unknown. For cases where the sign convention of the yaw rate is known, a standard name of platform_yaw_rate_fore_starboard or platform_yaw_rate_fore_port should be chosen, as appropriate. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_yaw_rate_fore_port.json b/data_descriptors/standard_name/platform_yaw_rate_fore_port.json index f66f47322..89d7fee2d 100644 --- a/data_descriptors/standard_name/platform_yaw_rate_fore_port.json +++ b/data_descriptors/standard_name/platform_yaw_rate_fore_port.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_yaw_rate_fore_port", + "id": "platform_yaw_rate_fore_port", "type": "standard_name", "name": "platform_yaw_rate_fore_port", "description": "\"Yaw rate\" is the rate of rotation about the local vertical axis. Yaw rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. \"Fore port\" indicates that positive values of yaw rate represent the front of the platform moving to the left as viewed by an observer on top of the platform facing forward. The standard name platform_yaw_rate_fore_starboard should be used for data having the opposite sign convention. The standard name platform_yaw_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_yaw_rate_fore_starboard.json b/data_descriptors/standard_name/platform_yaw_rate_fore_starboard.json index 42a77e087..ec7391277 100644 --- a/data_descriptors/standard_name/platform_yaw_rate_fore_starboard.json +++ b/data_descriptors/standard_name/platform_yaw_rate_fore_starboard.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_yaw_rate_fore_starboard", + "id": "platform_yaw_rate_fore_starboard", "type": "standard_name", "name": "platform_yaw_rate_fore_starboard", "description": "\"Yaw rate\" is the rate of rotation about the local vertical axis. Yaw rate might not include changes to the \"at rest\" rotation of the platform with respect to the axis of rotation, which may change over time. \"Fore starboard\" indicates that positive values of yaw rate represent the front of the platform moving to the right as viewed by an observer on top of the platform facing forward. The standard name platform_yaw_rate_fore_port should be used for data having the opposite sign convention. The standard name platform_yaw_rate should be chosen only if the sign convention of the data is unknown. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/platform_zenith_angle.json b/data_descriptors/standard_name/platform_zenith_angle.json index f42680bd2..dc28936d4 100644 --- a/data_descriptors/standard_name/platform_zenith_angle.json +++ b/data_descriptors/standard_name/platform_zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/platform_zenith_angle", + "id": "platform_zenith_angle", "type": "standard_name", "name": "platform_zenith_angle", "description": "Platform zenith angle is the the angle between the line of sight to the platform and the local zenith at the observation target. This angle is measured starting from directly overhead and its range is from zero (directly overhead the observation target) to 180 degrees (directly below the observation target). Local zenith is a line perpendicular to the Earth's surface at a given location. \"Observation target\" means a location on the Earth defined by the sensor performing the observations. A standard name also exists for sensor_zenith_angle. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated zenith angle. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/potential_energy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/potential_energy_content_of_atmosphere_layer.json index 8ebe6e554..69787bf58 100644 --- a/data_descriptors/standard_name/potential_energy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/potential_energy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/potential_energy_content_of_atmosphere_layer", + "id": "potential_energy_content_of_atmosphere_layer", "type": "standard_name", "name": "potential_energy_content_of_atmosphere_layer", "description": "\"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/potential_vorticity_of_atmosphere_layer.json b/data_descriptors/standard_name/potential_vorticity_of_atmosphere_layer.json index 5ef061ab0..613474346 100644 --- a/data_descriptors/standard_name/potential_vorticity_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/potential_vorticity_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/potential_vorticity_of_atmosphere_layer", + "id": "potential_vorticity_of_atmosphere_layer", "type": "standard_name", "name": "potential_vorticity_of_atmosphere_layer", "description": "\"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Atmosphere potential vorticity is the vertically averaged absolute vorticity of a layer of the atmosphere divided by the pressure difference from the bottom to the top of the layer.", diff --git a/data_descriptors/standard_name/potential_vorticity_of_ocean_layer.json b/data_descriptors/standard_name/potential_vorticity_of_ocean_layer.json index b0a72255c..c89bd7c8c 100644 --- a/data_descriptors/standard_name/potential_vorticity_of_ocean_layer.json +++ b/data_descriptors/standard_name/potential_vorticity_of_ocean_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/potential_vorticity_of_ocean_layer", + "id": "potential_vorticity_of_ocean_layer", "type": "standard_name", "name": "potential_vorticity_of_ocean_layer", "description": "\"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Ocean potential vorticity is the vertically averaged absolute vorticity of a layer of the ocean divided by the thickness of the layer.", diff --git a/data_descriptors/standard_name/precipitation_amount.json b/data_descriptors/standard_name/precipitation_amount.json index 5143558ed..41e92308f 100644 --- a/data_descriptors/standard_name/precipitation_amount.json +++ b/data_descriptors/standard_name/precipitation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/precipitation_amount", + "id": "precipitation_amount", "type": "standard_name", "name": "precipitation_amount", "description": "\"Amount\" means mass per unit area. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases.", diff --git a/data_descriptors/standard_name/precipitation_flux.json b/data_descriptors/standard_name/precipitation_flux.json index 64d13c213..24d4c34b3 100644 --- a/data_descriptors/standard_name/precipitation_flux.json +++ b/data_descriptors/standard_name/precipitation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/precipitation_flux", + "id": "precipitation_flux", "type": "standard_name", "name": "precipitation_flux", "description": "\"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/precipitation_flux_containing_17O.json b/data_descriptors/standard_name/precipitation_flux_containing_17O.json index bdac19108..78159108a 100644 --- a/data_descriptors/standard_name/precipitation_flux_containing_17O.json +++ b/data_descriptors/standard_name/precipitation_flux_containing_17O.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/precipitation_flux_containing_17O", + "id": "precipitation_flux_containing_17O", "type": "standard_name", "name": "precipitation_flux_containing_17O", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The chemical formula for water is H2O. \"O\" means the element \"oxygen\" and \"17O\" is the stable isotope \"oxygen-17\".", diff --git a/data_descriptors/standard_name/precipitation_flux_containing_18O.json b/data_descriptors/standard_name/precipitation_flux_containing_18O.json index f3c2cd2e4..e0ed0f963 100644 --- a/data_descriptors/standard_name/precipitation_flux_containing_18O.json +++ b/data_descriptors/standard_name/precipitation_flux_containing_18O.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/precipitation_flux_containing_18O", + "id": "precipitation_flux_containing_18O", "type": "standard_name", "name": "precipitation_flux_containing_18O", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The chemical formula for water is H2O. \"O\" means the element \"oxygen\" and \"18O\" is the stable isotope \"oxygen-18\".", diff --git a/data_descriptors/standard_name/precipitation_flux_containing_single_2H.json b/data_descriptors/standard_name/precipitation_flux_containing_single_2H.json index e62fd3129..b29192a9d 100644 --- a/data_descriptors/standard_name/precipitation_flux_containing_single_2H.json +++ b/data_descriptors/standard_name/precipitation_flux_containing_single_2H.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/precipitation_flux_containing_single_2H", + "id": "precipitation_flux_containing_single_2H", "type": "standard_name", "name": "precipitation_flux_containing_single_2H", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The chemical formula for water is H2O. \"H\" means the element \"hydrogen\" and \"2H\" is the stable isotope \"hydrogen-2\", usually called \"deuterium\". The construction \"X_containing_single_Y\" means the standard name refers to only that part of X composed of molecules containing a single atom of isotope Y.", diff --git a/data_descriptors/standard_name/precipitation_flux_onto_canopy.json b/data_descriptors/standard_name/precipitation_flux_onto_canopy.json index 01030a5d0..5fd883410 100644 --- a/data_descriptors/standard_name/precipitation_flux_onto_canopy.json +++ b/data_descriptors/standard_name/precipitation_flux_onto_canopy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/precipitation_flux_onto_canopy", + "id": "precipitation_flux_onto_canopy", "type": "standard_name", "name": "precipitation_flux_onto_canopy", "description": "\"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/predominant_precipitation_type_at_surface.json b/data_descriptors/standard_name/predominant_precipitation_type_at_surface.json index 8ddf31554..353dc29e3 100644 --- a/data_descriptors/standard_name/predominant_precipitation_type_at_surface.json +++ b/data_descriptors/standard_name/predominant_precipitation_type_at_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/predominant_precipitation_type_at_surface", + "id": "predominant_precipitation_type_at_surface", "type": "standard_name", "name": "predominant_precipitation_type_at_surface", "description": "A variable with the standard name predominant_precipitation_type_at_surface contains strings which indicate the character of the predominant precipitating hydrometeor at a location or grid cell. These strings have not yet been standardised. Alternatively, the data variable may contain integers which can be translated to strings using flag_values and flag_meanings attributes. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/pressure_at_effective_cloud_top_defined_by_infrared_radiation.json b/data_descriptors/standard_name/pressure_at_effective_cloud_top_defined_by_infrared_radiation.json index 55dda3dda..33e92dc90 100644 --- a/data_descriptors/standard_name/pressure_at_effective_cloud_top_defined_by_infrared_radiation.json +++ b/data_descriptors/standard_name/pressure_at_effective_cloud_top_defined_by_infrared_radiation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/pressure_at_effective_cloud_top_defined_by_infrared_radiation", + "id": "pressure_at_effective_cloud_top_defined_by_infrared_radiation", "type": "standard_name", "name": "pressure_at_effective_cloud_top_defined_by_infrared_radiation", "description": "The \"effective cloud top defined by infrared radiation\" is (approximately) the geometric height above the surface that is one optical depth at infrared wavelengths (in the region of 11 micrometers) below the cloud top that would be detected by visible and lidar techniques. Reference: Minnis, P. et al 2011 CERES Edition-2 Cloud Property Retrievals Using TRMM VIRS and Terra and Aqua MODIS Data x2014; Part I: Algorithms IEEE Transactions on Geoscience and Remote Sensing, 49(11), 4374-4400. doi: http://dx.doi.org/10.1109/TGRS.2011.2144601.", diff --git a/data_descriptors/standard_name/probability_distribution_of_wind_from_direction_over_time.json b/data_descriptors/standard_name/probability_distribution_of_wind_from_direction_over_time.json index d5919ec30..3ad70f35e 100644 --- a/data_descriptors/standard_name/probability_distribution_of_wind_from_direction_over_time.json +++ b/data_descriptors/standard_name/probability_distribution_of_wind_from_direction_over_time.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/probability_distribution_of_wind_from_direction_over_time", + "id": "probability_distribution_of_wind_from_direction_over_time", "type": "standard_name", "name": "probability_distribution_of_wind_from_direction_over_time", "description": "The construction \"probability_distribution_of_X_over_Z\" means that the data variable is a number in the range 0.0-1.0 for each range of X, where X varies over Z. The data variable should have an axis for X. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (\"wind_from_direction\") (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (\"wind_to_direction\") (eastward, southward, etc.).", diff --git a/data_descriptors/standard_name/product_of_air_temperature_and_specific_humidity.json b/data_descriptors/standard_name/product_of_air_temperature_and_specific_humidity.json index eff354d21..70926f32d 100644 --- a/data_descriptors/standard_name/product_of_air_temperature_and_specific_humidity.json +++ b/data_descriptors/standard_name/product_of_air_temperature_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_air_temperature_and_specific_humidity", + "id": "product_of_air_temperature_and_specific_humidity", "type": "standard_name", "name": "product_of_air_temperature_and_specific_humidity", "description": "The phrase \"product_of_X_and_Y\" means X*Y. \"specific\" means per unit mass. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. Specific humidity is the mass fraction of water vapor in (moist) air. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_salinity.json b/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_salinity.json index 98212273b..d297c9990 100644 --- a/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_salinity.json +++ b/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_sea_water_velocity_and_salinity", + "id": "product_of_eastward_sea_water_velocity_and_salinity", "type": "standard_name", "name": "product_of_eastward_sea_water_velocity_and_salinity", "description": "\"product_of_X_and_Y\" means X*Y. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_temperature.json b/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_temperature.json index b33c1846f..461256911 100644 --- a/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_temperature.json +++ b/data_descriptors/standard_name/product_of_eastward_sea_water_velocity_and_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_sea_water_velocity_and_temperature", + "id": "product_of_eastward_sea_water_velocity_and_temperature", "type": "standard_name", "name": "product_of_eastward_sea_water_velocity_and_temperature", "description": "The phrase \"product_of_X_and_Y\" means X*Y. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_eastward_wind_and_air_temperature.json b/data_descriptors/standard_name/product_of_eastward_wind_and_air_temperature.json index 3862fd065..f479f3a60 100644 --- a/data_descriptors/standard_name/product_of_eastward_wind_and_air_temperature.json +++ b/data_descriptors/standard_name/product_of_eastward_wind_and_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_wind_and_air_temperature", + "id": "product_of_eastward_wind_and_air_temperature", "type": "standard_name", "name": "product_of_eastward_wind_and_air_temperature", "description": "The phrase \"product_of_X_and_Y\" means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_eastward_wind_and_geopotential_height.json b/data_descriptors/standard_name/product_of_eastward_wind_and_geopotential_height.json index 29519d8e4..84543f052 100644 --- a/data_descriptors/standard_name/product_of_eastward_wind_and_geopotential_height.json +++ b/data_descriptors/standard_name/product_of_eastward_wind_and_geopotential_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_wind_and_geopotential_height", + "id": "product_of_eastward_wind_and_geopotential_height", "type": "standard_name", "name": "product_of_eastward_wind_and_geopotential_height", "description": "\"product_of_X_and_Y\" means X*Y. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure.json b/data_descriptors/standard_name/product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure.json index a9f610761..e4ffb34a1 100644 --- a/data_descriptors/standard_name/product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure.json +++ b/data_descriptors/standard_name/product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure", + "id": "product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure", "type": "standard_name", "name": "product_of_eastward_wind_and_lagrangian_tendency_of_air_pressure", "description": "The phrase \"product_of_X_and_Y\" means X*Y. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The phrase \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/product_of_eastward_wind_and_northward_wind.json b/data_descriptors/standard_name/product_of_eastward_wind_and_northward_wind.json index 6e0ad9687..879e50f75 100644 --- a/data_descriptors/standard_name/product_of_eastward_wind_and_northward_wind.json +++ b/data_descriptors/standard_name/product_of_eastward_wind_and_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_wind_and_northward_wind", + "id": "product_of_eastward_wind_and_northward_wind", "type": "standard_name", "name": "product_of_eastward_wind_and_northward_wind", "description": "\"product_of_X_and_Y\" means X*Y. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/product_of_eastward_wind_and_specific_humidity.json b/data_descriptors/standard_name/product_of_eastward_wind_and_specific_humidity.json index 0155b43d6..1af91380b 100644 --- a/data_descriptors/standard_name/product_of_eastward_wind_and_specific_humidity.json +++ b/data_descriptors/standard_name/product_of_eastward_wind_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_wind_and_specific_humidity", + "id": "product_of_eastward_wind_and_specific_humidity", "type": "standard_name", "name": "product_of_eastward_wind_and_specific_humidity", "description": "\"product_of_X_and_Y\" means X*Y. \"specific\" means per unit mass. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Specific humidity is the mass fraction of water vapor in (moist) air. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/product_of_eastward_wind_and_upward_air_velocity.json b/data_descriptors/standard_name/product_of_eastward_wind_and_upward_air_velocity.json index e71bcdfaa..fc4e26342 100644 --- a/data_descriptors/standard_name/product_of_eastward_wind_and_upward_air_velocity.json +++ b/data_descriptors/standard_name/product_of_eastward_wind_and_upward_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_eastward_wind_and_upward_air_velocity", + "id": "product_of_eastward_wind_and_upward_air_velocity", "type": "standard_name", "name": "product_of_eastward_wind_and_upward_air_velocity", "description": "\"product_of_X_and_Y\" means X*Y. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) Upward air velocity is the vertical component of the 3D air velocity vector.", diff --git a/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_air_temperature.json b/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_air_temperature.json index 50e5385a1..6bfcb5e81 100644 --- a/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_air_temperature.json +++ b/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_lagrangian_tendency_of_air_pressure_and_air_temperature", + "id": "product_of_lagrangian_tendency_of_air_pressure_and_air_temperature", "type": "standard_name", "name": "product_of_lagrangian_tendency_of_air_pressure_and_air_temperature", "description": "The phrase \"product_of_X_and_Y\" means X*Y. The phrase \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height.json b/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height.json index 48fb47873..83640ad08 100644 --- a/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height.json +++ b/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height", + "id": "product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height", "type": "standard_name", "name": "product_of_lagrangian_tendency_of_air_pressure_and_geopotential_height", "description": "The phrase \"product_of_X_and_Y\" means X*Y. The phrase \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", diff --git a/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity.json b/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity.json index 1888bfaaa..dbebfd01c 100644 --- a/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity.json +++ b/data_descriptors/standard_name/product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity", + "id": "product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity", "type": "standard_name", "name": "product_of_lagrangian_tendency_of_air_pressure_and_specific_humidity", "description": "The phrase \"product_of_X_and_Y\" means X*Y. The phrase \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation. \"Specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_salinity.json b/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_salinity.json index 1de7b5f5a..fc754465d 100644 --- a/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_salinity.json +++ b/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_sea_water_velocity_and_salinity", + "id": "product_of_northward_sea_water_velocity_and_salinity", "type": "standard_name", "name": "product_of_northward_sea_water_velocity_and_salinity", "description": "\"product_of_X_and_Y\" means X*Y. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_temperature.json b/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_temperature.json index e5e9b1e17..8a315555c 100644 --- a/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_temperature.json +++ b/data_descriptors/standard_name/product_of_northward_sea_water_velocity_and_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_sea_water_velocity_and_temperature", + "id": "product_of_northward_sea_water_velocity_and_temperature", "type": "standard_name", "name": "product_of_northward_sea_water_velocity_and_temperature", "description": "The phrase \"product_of_X_and_Y\" means X*Y. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_northward_wind_and_air_temperature.json b/data_descriptors/standard_name/product_of_northward_wind_and_air_temperature.json index c8673f9ad..6951b2403 100644 --- a/data_descriptors/standard_name/product_of_northward_wind_and_air_temperature.json +++ b/data_descriptors/standard_name/product_of_northward_wind_and_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_wind_and_air_temperature", + "id": "product_of_northward_wind_and_air_temperature", "type": "standard_name", "name": "product_of_northward_wind_and_air_temperature", "description": "The phrase \"product_of_X_and_Y\" means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_northward_wind_and_geopotential_height.json b/data_descriptors/standard_name/product_of_northward_wind_and_geopotential_height.json index ff92c0d35..844d7eba3 100644 --- a/data_descriptors/standard_name/product_of_northward_wind_and_geopotential_height.json +++ b/data_descriptors/standard_name/product_of_northward_wind_and_geopotential_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_wind_and_geopotential_height", + "id": "product_of_northward_wind_and_geopotential_height", "type": "standard_name", "name": "product_of_northward_wind_and_geopotential_height", "description": "\"product_of_X_and_Y\" means X*Y. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/product_of_northward_wind_and_lagrangian_tendency_of_air_pressure.json b/data_descriptors/standard_name/product_of_northward_wind_and_lagrangian_tendency_of_air_pressure.json index 5546c5b86..38cf49213 100644 --- a/data_descriptors/standard_name/product_of_northward_wind_and_lagrangian_tendency_of_air_pressure.json +++ b/data_descriptors/standard_name/product_of_northward_wind_and_lagrangian_tendency_of_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_wind_and_lagrangian_tendency_of_air_pressure", + "id": "product_of_northward_wind_and_lagrangian_tendency_of_air_pressure", "type": "standard_name", "name": "product_of_northward_wind_and_lagrangian_tendency_of_air_pressure", "description": "The phrase \"product_of_X_and_Y\" means X*Y. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The phrase \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/product_of_northward_wind_and_specific_humidity.json b/data_descriptors/standard_name/product_of_northward_wind_and_specific_humidity.json index 769322a05..3a615e292 100644 --- a/data_descriptors/standard_name/product_of_northward_wind_and_specific_humidity.json +++ b/data_descriptors/standard_name/product_of_northward_wind_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_wind_and_specific_humidity", + "id": "product_of_northward_wind_and_specific_humidity", "type": "standard_name", "name": "product_of_northward_wind_and_specific_humidity", "description": "\"product_of_X_and_Y\" means X*Y. \"specific\" means per unit mass. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Specific humidity is the mass fraction of water vapor in (moist) air. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/product_of_northward_wind_and_upward_air_velocity.json b/data_descriptors/standard_name/product_of_northward_wind_and_upward_air_velocity.json index 4a5e167c5..40974c247 100644 --- a/data_descriptors/standard_name/product_of_northward_wind_and_upward_air_velocity.json +++ b/data_descriptors/standard_name/product_of_northward_wind_and_upward_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_northward_wind_and_upward_air_velocity", + "id": "product_of_northward_wind_and_upward_air_velocity", "type": "standard_name", "name": "product_of_northward_wind_and_upward_air_velocity", "description": "\"product_of_X_and_Y\" means X*Y. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) Upward air velocity is the vertical component of the 3D air velocity vector.", diff --git a/data_descriptors/standard_name/product_of_upward_air_velocity_and_air_temperature.json b/data_descriptors/standard_name/product_of_upward_air_velocity_and_air_temperature.json index c0ea7b372..b7ce3c426 100644 --- a/data_descriptors/standard_name/product_of_upward_air_velocity_and_air_temperature.json +++ b/data_descriptors/standard_name/product_of_upward_air_velocity_and_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_upward_air_velocity_and_air_temperature", + "id": "product_of_upward_air_velocity_and_air_temperature", "type": "standard_name", "name": "product_of_upward_air_velocity_and_air_temperature", "description": "The phrase \"product_of_X_and_Y\" means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/product_of_upward_air_velocity_and_specific_humidity.json b/data_descriptors/standard_name/product_of_upward_air_velocity_and_specific_humidity.json index ccd3158ae..ac070fb52 100644 --- a/data_descriptors/standard_name/product_of_upward_air_velocity_and_specific_humidity.json +++ b/data_descriptors/standard_name/product_of_upward_air_velocity_and_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_upward_air_velocity_and_specific_humidity", + "id": "product_of_upward_air_velocity_and_specific_humidity", "type": "standard_name", "name": "product_of_upward_air_velocity_and_specific_humidity", "description": "\"product_of_X_and_Y\" means X*Y. \"specific\" means per unit mass. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Specific humidity is the mass fraction of water vapor in (moist) air. Upward air velocity is the vertical component of the 3D air velocity vector.", diff --git a/data_descriptors/standard_name/product_of_wind_speed_and_water_vapor_saturation_deficit_in_air.json b/data_descriptors/standard_name/product_of_wind_speed_and_water_vapor_saturation_deficit_in_air.json index 8729a3b43..3c28f4b89 100644 --- a/data_descriptors/standard_name/product_of_wind_speed_and_water_vapor_saturation_deficit_in_air.json +++ b/data_descriptors/standard_name/product_of_wind_speed_and_water_vapor_saturation_deficit_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/product_of_wind_speed_and_water_vapor_saturation_deficit_in_air", + "id": "product_of_wind_speed_and_water_vapor_saturation_deficit_in_air", "type": "standard_name", "name": "product_of_wind_speed_and_water_vapor_saturation_deficit_in_air", "description": "The product of windspeed and vapor pressure deficit is referred to as the Hot-Dry-Windy Index (HDW) for interpreting fire weather. It is a fire weather index that indicates the influence that the atmosphere has on a fire through wind, heat, and moisture (cf. https://www.bia.gov/sites/default/files/dup/assets/public/pdf/idc-020513.pdf). The units of HDW do not have an established physical significance for fire processes. As a fire weather index, it should be expressed in units of hPa m s-1.", diff --git a/data_descriptors/standard_name/projection_x_angular_coordinate.json b/data_descriptors/standard_name/projection_x_angular_coordinate.json index cd2421b48..00c5c6d19 100644 --- a/data_descriptors/standard_name/projection_x_angular_coordinate.json +++ b/data_descriptors/standard_name/projection_x_angular_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/projection_x_angular_coordinate", + "id": "projection_x_angular_coordinate", "type": "standard_name", "name": "projection_x_angular_coordinate", "description": "\"x\" indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. Angular projection coordinates are angular distances in the x- and y-directions on a plane onto which the surface of the Earth has been projected according to a map projection. The relationship between the angular projection coordinates and latitude and longitude is described by the grid_mapping.", diff --git a/data_descriptors/standard_name/projection_x_coordinate.json b/data_descriptors/standard_name/projection_x_coordinate.json index 109710ed4..a7216b205 100644 --- a/data_descriptors/standard_name/projection_x_coordinate.json +++ b/data_descriptors/standard_name/projection_x_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/projection_x_coordinate", + "id": "projection_x_coordinate", "type": "standard_name", "name": "projection_x_coordinate", "description": "\"x\" indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. Projection coordinates are distances in the x- and y-directions on a plane onto which the surface of the Earth has been projected according to a map projection. The relationship between the projection coordinates and latitude and longitude is described by the grid_mapping.", diff --git a/data_descriptors/standard_name/projection_y_angular_coordinate.json b/data_descriptors/standard_name/projection_y_angular_coordinate.json index c5661b737..cd0350cf7 100644 --- a/data_descriptors/standard_name/projection_y_angular_coordinate.json +++ b/data_descriptors/standard_name/projection_y_angular_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/projection_y_angular_coordinate", + "id": "projection_y_angular_coordinate", "type": "standard_name", "name": "projection_y_angular_coordinate", "description": "\"y\" indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. Angular projection coordinates are angular distances in the x- and y-directions on a plane onto which the surface of the Earth has been projected according to a map projection. The relationship between the angular projection coordinates and latitude and longitude is described by the grid_mapping.", diff --git a/data_descriptors/standard_name/projection_y_coordinate.json b/data_descriptors/standard_name/projection_y_coordinate.json index b2a05c583..63ccf637d 100644 --- a/data_descriptors/standard_name/projection_y_coordinate.json +++ b/data_descriptors/standard_name/projection_y_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/projection_y_coordinate", + "id": "projection_y_coordinate", "type": "standard_name", "name": "projection_y_coordinate", "description": "\"y\" indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. Projection coordinates are distances in the x- and y-directions on a plane onto which the surface of the Earth has been projected according to a map projection. The relationship between the projection coordinates and latitude and longitude is described by the grid_mapping.", diff --git a/data_descriptors/standard_name/proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water.json b/data_descriptors/standard_name/proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water.json index 1793dcc74..9424cc072 100644 --- a/data_descriptors/standard_name/proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water.json +++ b/data_descriptors/standard_name/proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water", + "id": "proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water", "type": "standard_name", "name": "proportion_of_acceptable_signal_returns_from_acoustic_instrument_in_sea_water", "description": "The phrase \"proportion_of_acceptable_signal_returns\" means the fraction of a collection (ensemble) of returned signal transmissions that have passed a set of automatic quality control criteria. For an ADCP (acoustic doppler current profiler) the rejection criteria include low correlation, large error velocity and fish detection. The dimensionless proportion is often but not exclusively expressed as a percentage, when it is referred to as \"percent good\".", diff --git a/data_descriptors/standard_name/quality_flag.json b/data_descriptors/standard_name/quality_flag.json index fc301ddbd..0534c0923 100644 --- a/data_descriptors/standard_name/quality_flag.json +++ b/data_descriptors/standard_name/quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/quality_flag", + "id": "quality_flag", "type": "standard_name", "name": "quality_flag", "description": "A variable with the standard name of quality_flag contains an indication of assessed quality information of another data variable. The linkage between the data variable and the variable or variables with the standard_name of quality_flag is achieved using the ancillary_variables attribute.", diff --git a/data_descriptors/standard_name/radial_sea_water_velocity_away_from_instrument.json b/data_descriptors/standard_name/radial_sea_water_velocity_away_from_instrument.json index 30ebfe4d4..04faec0e0 100644 --- a/data_descriptors/standard_name/radial_sea_water_velocity_away_from_instrument.json +++ b/data_descriptors/standard_name/radial_sea_water_velocity_away_from_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radial_sea_water_velocity_away_from_instrument", + "id": "radial_sea_water_velocity_away_from_instrument", "type": "standard_name", "name": "radial_sea_water_velocity_away_from_instrument", "description": "A velocity is a vector quantity. \"Radial velocity away from instrument\" means the component of the velocity along the line of sight of the instrument where positive implies movement away from the instrument (i.e. outward). The \"instrument\" (examples are radar and lidar) is the device used to make an observation. A standard name referring to radial velocity \"toward_instrument\" should be used for a data variable having the opposite sign convention.", diff --git a/data_descriptors/standard_name/radial_sea_water_velocity_toward_instrument.json b/data_descriptors/standard_name/radial_sea_water_velocity_toward_instrument.json index c99fb8598..8fa29f3b8 100644 --- a/data_descriptors/standard_name/radial_sea_water_velocity_toward_instrument.json +++ b/data_descriptors/standard_name/radial_sea_water_velocity_toward_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radial_sea_water_velocity_toward_instrument", + "id": "radial_sea_water_velocity_toward_instrument", "type": "standard_name", "name": "radial_sea_water_velocity_toward_instrument", "description": "A velocity is a vector quantity. \"Radial velocity toward instrument\" means the component of the velocity along the line of sight of the instrument where positive implies movement toward the instrument (i.e. inward). The \"instrument\" (examples are radar and lidar) is the device used to make an observation. A standard name referring to radial velocity \"away_from_instrument\" should be used for a data variable having the opposite sign convention.", diff --git a/data_descriptors/standard_name/radial_velocity_of_scatterers_away_from_instrument.json b/data_descriptors/standard_name/radial_velocity_of_scatterers_away_from_instrument.json index 09a6af691..b01c284d8 100644 --- a/data_descriptors/standard_name/radial_velocity_of_scatterers_away_from_instrument.json +++ b/data_descriptors/standard_name/radial_velocity_of_scatterers_away_from_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radial_velocity_of_scatterers_away_from_instrument", + "id": "radial_velocity_of_scatterers_away_from_instrument", "type": "standard_name", "name": "radial_velocity_of_scatterers_away_from_instrument", "description": "A velocity is a vector quantity. \"Radial velocity away from instrument\" means the component of the velocity along the line of sight of the instrument where positive implies movement away from the instrument (i.e. outward). The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities), of whatever kind the instrument detects. A standard name referring to radial velocity \"toward_instrument\" should be used for a data variable having the opposite sign convention.", diff --git a/data_descriptors/standard_name/radial_velocity_of_scatterers_toward_instrument.json b/data_descriptors/standard_name/radial_velocity_of_scatterers_toward_instrument.json index 4ae024538..c7efa94aa 100644 --- a/data_descriptors/standard_name/radial_velocity_of_scatterers_toward_instrument.json +++ b/data_descriptors/standard_name/radial_velocity_of_scatterers_toward_instrument.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radial_velocity_of_scatterers_toward_instrument", + "id": "radial_velocity_of_scatterers_toward_instrument", "type": "standard_name", "name": "radial_velocity_of_scatterers_toward_instrument", "description": "A velocity is a vector quantity. \"Radial velocity toward instrument\" means the component of the velocity along the line of sight of the instrument where positive implies movement toward the instrument (i.e. inward). The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities), of whatever kind the instrument detects. A standard name referring to radial velocity \"away_from_instrument\" should be used for a data variable having the opposite sign convention.", diff --git a/data_descriptors/standard_name/radiation_frequency.json b/data_descriptors/standard_name/radiation_frequency.json index 74e27de1a..5fedc0427 100644 --- a/data_descriptors/standard_name/radiation_frequency.json +++ b/data_descriptors/standard_name/radiation_frequency.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radiation_frequency", + "id": "radiation_frequency", "type": "standard_name", "name": "radiation_frequency", "description": "Frequency is the number of oscillations of a wave per unit time. The radiation frequency can refer to any electromagnetic wave, such as light, heat radiation and radio waves.", diff --git a/data_descriptors/standard_name/radiation_wavelength.json b/data_descriptors/standard_name/radiation_wavelength.json index fa3ddeb3e..1a3908f58 100644 --- a/data_descriptors/standard_name/radiation_wavelength.json +++ b/data_descriptors/standard_name/radiation_wavelength.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radiation_wavelength", + "id": "radiation_wavelength", "type": "standard_name", "name": "radiation_wavelength", "description": "The radiation wavelength can refer to any electromagnetic wave, such as light, heat radiation and radio waves.", diff --git a/data_descriptors/standard_name/radio_signal_roundtrip_travel_time_in_air.json b/data_descriptors/standard_name/radio_signal_roundtrip_travel_time_in_air.json index 8e7285f6b..c696f913e 100644 --- a/data_descriptors/standard_name/radio_signal_roundtrip_travel_time_in_air.json +++ b/data_descriptors/standard_name/radio_signal_roundtrip_travel_time_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radio_signal_roundtrip_travel_time_in_air", + "id": "radio_signal_roundtrip_travel_time_in_air", "type": "standard_name", "name": "radio_signal_roundtrip_travel_time_in_air", "description": "Time it takes for a radio wave, that was transmitted by an instrument to propagate through the air to the volume of air where it is scattered and return back to an instrument. The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities in the air). A standard name referring to time taken for a radio signal to propagate from the emitting instrument to a scattering volume and back to an instrument.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_in_air.json index 7a0aae30f..a17c6d310 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_in_air", + "id": "radioactivity_concentration_in_air", "type": "standard_name", "name": "radioactivity_concentration_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_101Mo_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_101Mo_in_air.json index 6376619ad..f7676a4a0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_101Mo_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_101Mo_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_101Mo_in_air", + "id": "radioactivity_concentration_of_101Mo_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_101Mo_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mo\" means the element \"molybdenum\" and \"101Mo\" is the isotope \"molybdenum-101\" with a half-life of 1.01e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_101Tc_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_101Tc_in_air.json index 1f876ac19..d80ab0a66 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_101Tc_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_101Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_101Tc_in_air", + "id": "radioactivity_concentration_of_101Tc_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_101Tc_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"101Tc\" is the isotope \"technetium-101\" with a half-life of 9.86e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_102Mo_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_102Mo_in_air.json index 02419ad39..eb0bb356b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_102Mo_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_102Mo_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_102Mo_in_air", + "id": "radioactivity_concentration_of_102Mo_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_102Mo_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mo\" means the element \"molybdenum\" and \"102Mo\" is the isotope \"molybdenum-102\" with a half-life of 7.71e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_102Tc_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_102Tc_in_air.json index 1b3156797..25a614a9e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_102Tc_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_102Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_102Tc_in_air", + "id": "radioactivity_concentration_of_102Tc_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_102Tc_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"102Tc\" is the isotope \"technetium-102\" with a half-life of 6.12e-05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_102mTc_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_102mTc_in_air.json index 69c4c0330..4bbe57564 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_102mTc_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_102mTc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_102mTc_in_air", + "id": "radioactivity_concentration_of_102mTc_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_102mTc_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"102mTc\" is the metastable state of the isotope \"technetium-102\" with a half-life of 2.98e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_103Ru_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_103Ru_in_air.json index a82ff4c37..67ff27709 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_103Ru_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_103Ru_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_103Ru_in_air", + "id": "radioactivity_concentration_of_103Ru_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_103Ru_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ru\" means the element \"ruthenium\" and \"103Ru\" is the isotope \"ruthenium-103\" with a half-life of 3.95e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_103mRh_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_103mRh_in_air.json index 1809f2920..2f406ae2e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_103mRh_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_103mRh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_103mRh_in_air", + "id": "radioactivity_concentration_of_103mRh_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_103mRh_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"103mRh\" is the metastable state of the isotope \"rhodium-103\" with a half-life of 3.89e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_104Tc_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_104Tc_in_air.json index e7ba81895..056577f0d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_104Tc_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_104Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_104Tc_in_air", + "id": "radioactivity_concentration_of_104Tc_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_104Tc_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"104Tc\" is the isotope \"technetium-104\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_105Rh_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_105Rh_in_air.json index 7c4a6d282..1b89a9f41 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_105Rh_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_105Rh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_105Rh_in_air", + "id": "radioactivity_concentration_of_105Rh_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_105Rh_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"105Rh\" is the isotope \"rhodium-105\" with a half-life of 1.48e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_105Ru_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_105Ru_in_air.json index 6a6ae4532..5dcc356fa 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_105Ru_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_105Ru_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_105Ru_in_air", + "id": "radioactivity_concentration_of_105Ru_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_105Ru_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ru\" means the element \"ruthenium\" and \"105Ru\" is the isotope \"ruthenium-105\" with a half-life of 1.85e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_105mRh_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_105mRh_in_air.json index a9d7dea65..eca1837d0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_105mRh_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_105mRh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_105mRh_in_air", + "id": "radioactivity_concentration_of_105mRh_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_105mRh_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"105mRh\" is the metastable state of the isotope \"rhodium-105\" with a half-life of 4.41e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_106Rh_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_106Rh_in_air.json index a35c998e5..592fef029 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_106Rh_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_106Rh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_106Rh_in_air", + "id": "radioactivity_concentration_of_106Rh_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_106Rh_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"106Rh\" is the isotope \"rhodium-106\" with a half-life of 3.46e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_106Ru_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_106Ru_in_air.json index 804f911d7..bad5ebb71 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_106Ru_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_106Ru_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_106Ru_in_air", + "id": "radioactivity_concentration_of_106Ru_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_106Ru_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ru\" means the element \"ruthenium\" and \"106Ru\" is the isotope \"ruthenium-106\" with a half-life of 3.66e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_106mRh_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_106mRh_in_air.json index 1a67536a5..e018ada22 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_106mRh_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_106mRh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_106mRh_in_air", + "id": "radioactivity_concentration_of_106mRh_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_106mRh_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"106mRh\" is the metastable state of the isotope \"rhodium-106\" with a half-life of 9.09e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_107Pd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_107Pd_in_air.json index e3464c6d0..d5a321a81 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_107Pd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_107Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_107Pd_in_air", + "id": "radioactivity_concentration_of_107Pd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_107Pd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"107Pd\" is the isotope \"palladium-107\" with a half-life of 2.37e+09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_107Rh_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_107Rh_in_air.json index e32c503df..e258c7d45 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_107Rh_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_107Rh_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_107Rh_in_air", + "id": "radioactivity_concentration_of_107Rh_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_107Rh_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rh\" means the element \"rhodium\" and \"107Rh\" is the isotope \"rhodium-107\" with a half-life of 1.51e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_107mPd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_107mPd_in_air.json index b2ee9e57a..651dcfdd9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_107mPd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_107mPd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_107mPd_in_air", + "id": "radioactivity_concentration_of_107mPd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_107mPd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"107mPd\" is the metastable state of the isotope \"palladium-107\" with a half-life of 2.47e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_109Pd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_109Pd_in_air.json index 4f3a7c134..0db4c1cbe 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_109Pd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_109Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_109Pd_in_air", + "id": "radioactivity_concentration_of_109Pd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_109Pd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"109Pd\" is the isotope \"palladium-109\" with a half-life of 5.61e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_109mAg_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_109mAg_in_air.json index 068926c04..a221963ef 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_109mAg_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_109mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_109mAg_in_air", + "id": "radioactivity_concentration_of_109mAg_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_109mAg_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"109mAg\" is the metastable state of the isotope \"silver-109\" with a half-life of 4.58e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_110mAg_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_110mAg_in_air.json index 3eace7f7a..8831f373b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_110mAg_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_110mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_110mAg_in_air", + "id": "radioactivity_concentration_of_110mAg_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_110mAg_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"110mAg\" is the metastable state of the isotope \"silver-110\" with a half-life of 2.70e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_111Ag_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_111Ag_in_air.json index 0418722a3..76e1fc2cd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_111Ag_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_111Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_111Ag_in_air", + "id": "radioactivity_concentration_of_111Ag_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_111Ag_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"111Ag\" is the isotope \"silver-111\" with a half-life of 7.50e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_111Pd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_111Pd_in_air.json index 50d61e9ad..139407097 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_111Pd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_111Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_111Pd_in_air", + "id": "radioactivity_concentration_of_111Pd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_111Pd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"111Pd\" is the isotope \"palladium-111\" with a half-life of 1.53e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_111mAg_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_111mAg_in_air.json index 5db33edf0..54fd9930c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_111mAg_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_111mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_111mAg_in_air", + "id": "radioactivity_concentration_of_111mAg_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_111mAg_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"111mAg\" is the metastable state of the isotope \"silver-111\" with a half-life of 8.56e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_111mCd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_111mCd_in_air.json index b3713b142..7a4d436de 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_111mCd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_111mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_111mCd_in_air", + "id": "radioactivity_concentration_of_111mCd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_111mCd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"111mCd\" is the metastable state of the isotope \"cadmium-111\" with a half-life of 3.39e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_111mPd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_111mPd_in_air.json index d10b8ff26..5c2eb8fa8 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_111mPd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_111mPd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_111mPd_in_air", + "id": "radioactivity_concentration_of_111mPd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_111mPd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"111mPd\" is the metastable state of the isotope \"palladium-111\" with a half-life of 2.29e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_112Ag_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_112Ag_in_air.json index e901eff25..3c92b5d2a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_112Ag_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_112Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_112Ag_in_air", + "id": "radioactivity_concentration_of_112Ag_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_112Ag_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"112Ag\" is the isotope \"silver-112\" with a half-life of 1.30e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_112Pd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_112Pd_in_air.json index a469c5965..c5d950cc1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_112Pd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_112Pd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_112Pd_in_air", + "id": "radioactivity_concentration_of_112Pd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_112Pd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pd\" means the element \"palladium\" and \"112Pd\" is the isotope \"palladium-112\" with a half-life of 8.37e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_113Ag_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_113Ag_in_air.json index d59378659..3a06e120f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_113Ag_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_113Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_113Ag_in_air", + "id": "radioactivity_concentration_of_113Ag_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_113Ag_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"113Ag\" is the isotope \"silver-113\" with a half-life of 2.21e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_113Cd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_113Cd_in_air.json index 29ac91b4f..2add89bdf 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_113Cd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_113Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_113Cd_in_air", + "id": "radioactivity_concentration_of_113Cd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_113Cd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"113Cd\" is the isotope \"cadmium-113\" with a half-life of 3.29e+18 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_113mAg_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_113mAg_in_air.json index afca5df34..2c47dc156 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_113mAg_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_113mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_113mAg_in_air", + "id": "radioactivity_concentration_of_113mAg_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_113mAg_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"113mAg\" is the metastable state of the isotope \"silver-113\" with a half-life of 7.64e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_113mCd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_113mCd_in_air.json index c642b7457..40ebdf4e2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_113mCd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_113mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_113mCd_in_air", + "id": "radioactivity_concentration_of_113mCd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_113mCd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"113mCd\" is the metastable state of the isotope \"cadmium-113\" with a half-life of 5.31e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_113mIn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_113mIn_in_air.json index 976cfedf8..be3f3e8c0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_113mIn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_113mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_113mIn_in_air", + "id": "radioactivity_concentration_of_113mIn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_113mIn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"113mIn\" is the metastable state of the isotope \"indium-113\" with a half-life of 6.92e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_115Ag_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_115Ag_in_air.json index be8ee2c11..5e76413b6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_115Ag_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_115Ag_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_115Ag_in_air", + "id": "radioactivity_concentration_of_115Ag_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_115Ag_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"115Ag\" is the isotope \"silver-115\" with a half-life of 1.46e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_115Cd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_115Cd_in_air.json index 22d214897..7399854a4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_115Cd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_115Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_115Cd_in_air", + "id": "radioactivity_concentration_of_115Cd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_115Cd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"115Cd\" is the isotope \"cadmium-115\" with a half-life of 2.23e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_115In_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_115In_in_air.json index 2917d2b01..0ff1073f7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_115In_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_115In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_115In_in_air", + "id": "radioactivity_concentration_of_115In_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_115In_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"115In\" is the isotope \"indium-115\" with a half-life of 1.86e+18 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_115mAg_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_115mAg_in_air.json index 8f313483a..8a20baf86 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_115mAg_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_115mAg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_115mAg_in_air", + "id": "radioactivity_concentration_of_115mAg_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_115mAg_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ag\" means the element \"silver\" and \"115mAg\" is the metastable state of the isotope \"silver-115\" with a half-life of 1.97e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_115mCd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_115mCd_in_air.json index 50712a4b0..c2ec0f8b6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_115mCd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_115mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_115mCd_in_air", + "id": "radioactivity_concentration_of_115mCd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_115mCd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"115mCd\" is the metastable state of the isotope \"cadmium-115\" with a half-life of 4.46e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_115mIn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_115mIn_in_air.json index 9e102e249..5a1783236 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_115mIn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_115mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_115mIn_in_air", + "id": "radioactivity_concentration_of_115mIn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_115mIn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"115mIn\" is the metastable state of the isotope \"indium-115\" with a half-life of 1.87e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_116In_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_116In_in_air.json index 7f60c8778..b4c33b116 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_116In_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_116In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_116In_in_air", + "id": "radioactivity_concentration_of_116In_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_116In_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"116In\" is the isotope \"indium-116\" with a half-life of 1.64e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_116mIn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_116mIn_in_air.json index d56fe8e92..738ccde52 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_116mIn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_116mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_116mIn_in_air", + "id": "radioactivity_concentration_of_116mIn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_116mIn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"116mIn\" is the metastable state of the isotope \"indium-116\" with a half-life of 3.77e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_117Cd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_117Cd_in_air.json index 1a910ccaa..522cf1d2e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_117Cd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_117Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_117Cd_in_air", + "id": "radioactivity_concentration_of_117Cd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_117Cd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"117Cd\" is the isotope \"cadmium-117\" with a half-life of 1.08e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_117In_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_117In_in_air.json index a3e2e4514..aef3fa06d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_117In_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_117In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_117In_in_air", + "id": "radioactivity_concentration_of_117In_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_117In_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"117In\" is the isotope \"indium-117\" with a half-life of 3.05e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_117mCd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_117mCd_in_air.json index 0f2cef5e3..768e315c7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_117mCd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_117mCd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_117mCd_in_air", + "id": "radioactivity_concentration_of_117mCd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_117mCd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"117mCd\" is the metastable state of the isotope \"cadmium-117\" with a half-life of 1.42e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_117mIn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_117mIn_in_air.json index a280761fd..d17fe542d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_117mIn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_117mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_117mIn_in_air", + "id": "radioactivity_concentration_of_117mIn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_117mIn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"117mIn\" is the metastable state of the isotope \"indium-117\" with a half-life of 8.08e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_117mSn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_117mSn_in_air.json index 99cf80597..fd69840de 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_117mSn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_117mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_117mSn_in_air", + "id": "radioactivity_concentration_of_117mSn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_117mSn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"117mSn\" is the metastable state of the isotope \"tin-117\" with a half-life of 1.40e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_118Cd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_118Cd_in_air.json index 10f728633..511ce1fae 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_118Cd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_118Cd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_118Cd_in_air", + "id": "radioactivity_concentration_of_118Cd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_118Cd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cd\" means the element \"cadmium\" and \"118Cd\" is the isotope \"cadmium-118\" with a half-life of 3.49e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_118In_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_118In_in_air.json index e5856e666..2462429dd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_118In_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_118In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_118In_in_air", + "id": "radioactivity_concentration_of_118In_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_118In_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"118In\" is the isotope \"indium-118\" with a half-life of 5.77e-05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_118mIn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_118mIn_in_air.json index eb12f8a9c..8456a5faa 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_118mIn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_118mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_118mIn_in_air", + "id": "radioactivity_concentration_of_118mIn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_118mIn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"118mIn\" is the metastable state of the isotope \"indium-118\" with a half-life of 3.05e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_119In_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_119In_in_air.json index d427951b2..0f9b6aac0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_119In_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_119In_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_119In_in_air", + "id": "radioactivity_concentration_of_119In_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_119In_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"119In\" is the isotope \"indium-119\" with a half-life of 1.74e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_119mIn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_119mIn_in_air.json index a5e64f606..54fba9eee 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_119mIn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_119mIn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_119mIn_in_air", + "id": "radioactivity_concentration_of_119mIn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_119mIn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"In\" means the element \"indium\" and \"119mIn\" is the metastable state of the isotope \"indium-119\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_119mSn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_119mSn_in_air.json index 607d537ff..94c8401a9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_119mSn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_119mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_119mSn_in_air", + "id": "radioactivity_concentration_of_119mSn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_119mSn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"119mSn\" is the metastable state of the isotope \"tin-119\" with a half-life of 2.45e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_11C_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_11C_in_air.json index c15813ff1..a1c495b57 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_11C_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_11C_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_11C_in_air", + "id": "radioactivity_concentration_of_11C_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_11C_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"C\" means the element \"carbon\" and \"11C\" is the isotope \"carbon-11\" with a half-life of 1.41e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_121Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_121Sn_in_air.json index 3f0d6969a..82c7d8664 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_121Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_121Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_121Sn_in_air", + "id": "radioactivity_concentration_of_121Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_121Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"121Sn\" is the isotope \"tin-121\" with a half-life of 1.12e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_121mSn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_121mSn_in_air.json index 4ce224fb2..0dfe181ff 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_121mSn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_121mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_121mSn_in_air", + "id": "radioactivity_concentration_of_121mSn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_121mSn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"121mSn\" is the metastable state of the isotope \"tin-121\" with a half-life of 1.82e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_123Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_123Sn_in_air.json index d84e8219f..6aa60baba 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_123Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_123Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_123Sn_in_air", + "id": "radioactivity_concentration_of_123Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_123Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"123Sn\" is the isotope \"tin-123\" with a half-life of 1.29e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_123mSn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_123mSn_in_air.json index adefbb8a8..20d6a3813 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_123mSn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_123mSn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_123mSn_in_air", + "id": "radioactivity_concentration_of_123mSn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_123mSn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"123mSn\" is the metastable state of the isotope \"tin-123\" with a half-life of 2.78e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_124Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_124Sb_in_air.json index d98976d8d..c1e72391d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_124Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_124Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_124Sb_in_air", + "id": "radioactivity_concentration_of_124Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_124Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"124Sb\" is the isotope \"antimony-124\" with a half-life of 6.03e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_124mSb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_124mSb_in_air.json index ca489199e..c77c163e6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_124mSb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_124mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_124mSb_in_air", + "id": "radioactivity_concentration_of_124mSb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_124mSb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"124mSb\" is the metastable state of the isotope \"antimony-124\" with a half-life of 1.41e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_125Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_125Sb_in_air.json index 5ff116f5a..1c8172964 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_125Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_125Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_125Sb_in_air", + "id": "radioactivity_concentration_of_125Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_125Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"125Sb\" is the isotope \"antimony-125\" with a half-life of 9.97e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_125Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_125Sn_in_air.json index 91e521b71..6f037903f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_125Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_125Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_125Sn_in_air", + "id": "radioactivity_concentration_of_125Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_125Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"125Sn\" is the isotope \"tin-125\" with a half-life of 9.65e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_125mTe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_125mTe_in_air.json index 4cb326549..29991507e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_125mTe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_125mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_125mTe_in_air", + "id": "radioactivity_concentration_of_125mTe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_125mTe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"125mTe\" is the metastable state of the isotope \"tellurium-125\" with a half-life of 5.81e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_126Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_126Sb_in_air.json index 6e5fa9baf..f90a1f3b7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_126Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_126Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_126Sb_in_air", + "id": "radioactivity_concentration_of_126Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_126Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"126Sb\" is the isotope \"antimony-126\" with a half-life of 1.24e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_126Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_126Sn_in_air.json index 3751ef1f9..f8496b91a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_126Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_126Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_126Sn_in_air", + "id": "radioactivity_concentration_of_126Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_126Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"126Sn\" is the isotope \"tin-126\" with a half-life of 3.65e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_126mSb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_126mSb_in_air.json index 5c09110c2..b31abc22b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_126mSb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_126mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_126mSb_in_air", + "id": "radioactivity_concentration_of_126mSb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_126mSb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"126mSb\" is the metastable state of the isotope \"antimony-126\" with a half-life of 1.32e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_127Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_127Sb_in_air.json index 95b699e43..d3b186809 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_127Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_127Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_127Sb_in_air", + "id": "radioactivity_concentration_of_127Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_127Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"127Sb\" is the isotope \"antimony-127\" with a half-life of 3.80e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_127Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_127Sn_in_air.json index 0090f004d..2f44329cd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_127Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_127Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_127Sn_in_air", + "id": "radioactivity_concentration_of_127Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_127Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"127Sn\" is the isotope \"tin-127\" with a half-life of 8.84e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_127Te_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_127Te_in_air.json index dee291893..453a05df1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_127Te_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_127Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_127Te_in_air", + "id": "radioactivity_concentration_of_127Te_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_127Te_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"127Te\" is the isotope \"tellurium-127\" with a half-life of 3.91e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_127mTe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_127mTe_in_air.json index c29630884..bd65fa759 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_127mTe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_127mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_127mTe_in_air", + "id": "radioactivity_concentration_of_127mTe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_127mTe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"127mTe\" is the metastable state of the isotope \"tellurium-127\" with a half-life of 1.09e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_128Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_128Sb_in_air.json index 23399e6eb..70230c16c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_128Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_128Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_128Sb_in_air", + "id": "radioactivity_concentration_of_128Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_128Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"128Sb\" is the isotope \"antimony-128\" with a half-life of 3.75e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_128Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_128Sn_in_air.json index c94481c2a..6a48f95c4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_128Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_128Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_128Sn_in_air", + "id": "radioactivity_concentration_of_128Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_128Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"128Sn\" is the isotope \"tin-128\" with a half-life of 4.09e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_128mSb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_128mSb_in_air.json index 189a5ca81..e0ea4fdf7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_128mSb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_128mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_128mSb_in_air", + "id": "radioactivity_concentration_of_128mSb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_128mSb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"128mSb\" is the metastable state of the isotope \"antimony-128\" with a half-life of 7.23e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_129I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_129I_in_air.json index 2be731e72..db067279e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_129I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_129I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_129I_in_air", + "id": "radioactivity_concentration_of_129I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_129I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"129I\" is the isotope \"iodine-129\" with a half-life of 5.81e+09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_129Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_129Sb_in_air.json index e8e258426..68cdb87a6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_129Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_129Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_129Sb_in_air", + "id": "radioactivity_concentration_of_129Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_129Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"129Sb\" is the isotope \"antimony-129\" with a half-life of 1.81e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_129Te_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_129Te_in_air.json index f51b1d3ac..e89e258ee 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_129Te_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_129Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_129Te_in_air", + "id": "radioactivity_concentration_of_129Te_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_129Te_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"129Te\" is the isotope \"tellurium-129\" with a half-life of 4.86e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_129mTe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_129mTe_in_air.json index 798635189..e0ed7ee89 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_129mTe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_129mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_129mTe_in_air", + "id": "radioactivity_concentration_of_129mTe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_129mTe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"129mTe\" is the metastable state of the isotope \"tellurium-129\" with a half-life of 3.34e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_129mXe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_129mXe_in_air.json index 571c757a4..876740e72 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_129mXe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_129mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_129mXe_in_air", + "id": "radioactivity_concentration_of_129mXe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_129mXe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"129mXe\" is the metastable state of the isotope \"xenon-129\" with a half-life of 8.02e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_130I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_130I_in_air.json index e38176017..635c7c8a1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_130I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_130I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_130I_in_air", + "id": "radioactivity_concentration_of_130I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_130I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"130I\" is the isotope \"iodine-130\" with a half-life of 5.18e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_130Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_130Sb_in_air.json index 7c7a090af..1ca238944 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_130Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_130Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_130Sb_in_air", + "id": "radioactivity_concentration_of_130Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_130Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"130Sb\" is the isotope \"antimony-130\" with a half-life of 2.57e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_130Sn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_130Sn_in_air.json index e20b85910..4f5c17ff4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_130Sn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_130Sn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_130Sn_in_air", + "id": "radioactivity_concentration_of_130Sn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_130Sn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sn\" means the element \"tin\" and \"130Sn\" is the isotope \"tin-130\" with a half-life of 2.57e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_130mI_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_130mI_in_air.json index b5777c523..1fb4a1408 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_130mI_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_130mI_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_130mI_in_air", + "id": "radioactivity_concentration_of_130mI_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_130mI_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"130mI\" is the metastable state of the isotope \"iodine-130\" with a half-life of 6.17e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_130mSb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_130mSb_in_air.json index f37b1bfe1..5a9cf515d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_130mSb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_130mSb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_130mSb_in_air", + "id": "radioactivity_concentration_of_130mSb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_130mSb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"130mSb\" is the metastable state of the isotope \"antimony-130\" with a half-life of 4.58e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_131I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_131I_in_air.json index 035fea3bc..fe8838dd2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_131I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_131I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_131I_in_air", + "id": "radioactivity_concentration_of_131I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_131I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"131I\" is the isotope \"iodine-131\" with a half-life of 8.07e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_131Sb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_131Sb_in_air.json index 2e60a6bb3..904e0eaba 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_131Sb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_131Sb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_131Sb_in_air", + "id": "radioactivity_concentration_of_131Sb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_131Sb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sb\" means the element \"antimony\" and \"131Sb\" is the isotope \"antimony-131\" with a half-life of 1.60e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_131Te_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_131Te_in_air.json index 134167bc7..819ed34ce 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_131Te_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_131Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_131Te_in_air", + "id": "radioactivity_concentration_of_131Te_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_131Te_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"131Te\" is the isotope \"tellurium-131\" with a half-life of 1.74e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_131mTe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_131mTe_in_air.json index 060600872..43821b1fc 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_131mTe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_131mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_131mTe_in_air", + "id": "radioactivity_concentration_of_131mTe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_131mTe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"131mTe\" is the metastable state of the isotope \"tellurium-131\" with a half-life of 1.25e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_131mXe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_131mXe_in_air.json index e3ba73228..5914c035f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_131mXe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_131mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_131mXe_in_air", + "id": "radioactivity_concentration_of_131mXe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_131mXe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"131mXe\" is the metastable state of the isotope \"xenon-131\" with a half-life of 1.18e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_132I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_132I_in_air.json index 354e19c9e..7ae643a7c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_132I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_132I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_132I_in_air", + "id": "radioactivity_concentration_of_132I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_132I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"132I\" is the isotope \"iodine-132\" with a half-life of 9.60e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_132Te_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_132Te_in_air.json index 59f9a7eb4..cf76511ab 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_132Te_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_132Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_132Te_in_air", + "id": "radioactivity_concentration_of_132Te_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_132Te_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"132Te\" is the isotope \"tellurium-132\" with a half-life of 3.25e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_133I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_133I_in_air.json index eded3d132..a984b685d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_133I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_133I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_133I_in_air", + "id": "radioactivity_concentration_of_133I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_133I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"133I\" is the isotope \"iodine-133\" with a half-life of 8.71e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_133Te_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_133Te_in_air.json index ce5fc2514..f5bfc2867 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_133Te_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_133Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_133Te_in_air", + "id": "radioactivity_concentration_of_133Te_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_133Te_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"133Te\" is the isotope \"tellurium-133\" with a half-life of 8.68e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_133Xe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_133Xe_in_air.json index a749264a5..02f01414c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_133Xe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_133Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_133Xe_in_air", + "id": "radioactivity_concentration_of_133Xe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_133Xe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"133Xe\" is the isotope \"xenon-133\" with a half-life of 5.28e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_133mI_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_133mI_in_air.json index 555d15982..fafac5d9b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_133mI_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_133mI_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_133mI_in_air", + "id": "radioactivity_concentration_of_133mI_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_133mI_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"133mI\" is the metastable state of the isotope \"iodine-133\" with a half-life of 1.04e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_133mTe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_133mTe_in_air.json index 09b4d2d5d..15fb6e88a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_133mTe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_133mTe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_133mTe_in_air", + "id": "radioactivity_concentration_of_133mTe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_133mTe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"133mTe\" is the metastable state of the isotope \"tellurium-133\" with a half-life of 3.84e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_133mXe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_133mXe_in_air.json index 5dd6b99c6..88a250878 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_133mXe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_133mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_133mXe_in_air", + "id": "radioactivity_concentration_of_133mXe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_133mXe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"133mXe\" is the metastable state of the isotope \"xenon-133\" with a half-life of 2.26e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_134Cs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_134Cs_in_air.json index e50b380c0..ed0e68276 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_134Cs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_134Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_134Cs_in_air", + "id": "radioactivity_concentration_of_134Cs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_134Cs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"134Cs\" is the isotope \"cesium-134\" with a half-life of 7.50e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_134I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_134I_in_air.json index 3b3016fe5..01f6fbe5f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_134I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_134I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_134I_in_air", + "id": "radioactivity_concentration_of_134I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_134I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"134I\" is the isotope \"iodine-134\" with a half-life of 3.61e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_134Te_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_134Te_in_air.json index 3c053cbfd..6577d4742 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_134Te_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_134Te_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_134Te_in_air", + "id": "radioactivity_concentration_of_134Te_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_134Te_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Te\" means the element \"tellurium\" and \"134Te\" is the isotope \"tellurium-134\" with a half-life of 2.92e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_134mCs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_134mCs_in_air.json index f0dd2ab51..6f8fa1c24 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_134mCs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_134mCs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_134mCs_in_air", + "id": "radioactivity_concentration_of_134mCs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_134mCs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"134mCs\" is the metastable state of the isotope \"cesium-134\" with a half-life of 1.21e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_134mI_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_134mI_in_air.json index 662a320c6..38c0185ca 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_134mI_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_134mI_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_134mI_in_air", + "id": "radioactivity_concentration_of_134mI_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_134mI_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"134mI\" is the metastable state of the isotope \"iodine-134\" with a half-life of 2.50e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_134mXe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_134mXe_in_air.json index 3b6183fe7..0a432a220 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_134mXe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_134mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_134mXe_in_air", + "id": "radioactivity_concentration_of_134mXe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_134mXe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"134mXe\" is the metastable state of the isotope \"xenon-134\" with a half-life of 3.36e-06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_135Cs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_135Cs_in_air.json index 8cccaaab8..d19535284 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_135Cs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_135Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_135Cs_in_air", + "id": "radioactivity_concentration_of_135Cs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_135Cs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"135Cs\" is the isotope \"cesium-135\" with a half-life of 8.39e+08 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_135I_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_135I_in_air.json index 46e1858e7..8aa209614 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_135I_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_135I_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_135I_in_air", + "id": "radioactivity_concentration_of_135I_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_135I_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"I\" means the element \"iodine\" and \"135I\" is the isotope \"iodine-135\" with a half-life of 2.79e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_135Xe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_135Xe_in_air.json index e6039cd55..17792d4c4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_135Xe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_135Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_135Xe_in_air", + "id": "radioactivity_concentration_of_135Xe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_135Xe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"135Xe\" is the isotope \"xenon-135\" with a half-life of 3.82e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_135mBa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_135mBa_in_air.json index 64a1f2d90..723056346 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_135mBa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_135mBa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_135mBa_in_air", + "id": "radioactivity_concentration_of_135mBa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_135mBa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"135mBa\" is the metastable state of the isotope \"barium-135\" with a half-life of 1.20e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_135mCs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_135mCs_in_air.json index 0f36af7f8..50d88bb8f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_135mCs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_135mCs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_135mCs_in_air", + "id": "radioactivity_concentration_of_135mCs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_135mCs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"135mCs\" is the metastable state of the isotope \"cesium-135\" with a half-life of 3.68e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_135mXe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_135mXe_in_air.json index b876856d3..15efde1ad 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_135mXe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_135mXe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_135mXe_in_air", + "id": "radioactivity_concentration_of_135mXe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_135mXe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"135mXe\" is the metastable state of the isotope \"xenon-135\" with a half-life of 1.08e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_136Cs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_136Cs_in_air.json index 2ac308bbd..4638960a7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_136Cs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_136Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_136Cs_in_air", + "id": "radioactivity_concentration_of_136Cs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_136Cs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"136Cs\" is the isotope \"cesium-136\" with a half-life of 1.30e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_137Cs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_137Cs_in_air.json index 4756d1391..78ebf3e91 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_137Cs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_137Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_137Cs_in_air", + "id": "radioactivity_concentration_of_137Cs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_137Cs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"137Cs\" is the isotope \"cesium-137\" with a half-life of 1.10e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_137Xe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_137Xe_in_air.json index 3e3a25383..0611ea8bf 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_137Xe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_137Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_137Xe_in_air", + "id": "radioactivity_concentration_of_137Xe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_137Xe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"137Xe\" is the isotope \"xenon-137\" with a half-life of 2.71e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_137mBa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_137mBa_in_air.json index c35f385b7..f92dbdba7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_137mBa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_137mBa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_137mBa_in_air", + "id": "radioactivity_concentration_of_137mBa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_137mBa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"137mBa\" is the metastable state of the isotope \"barium-137\" with a half-life of 1.77e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_138Cs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_138Cs_in_air.json index c4786ea7a..8826ed464 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_138Cs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_138Cs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_138Cs_in_air", + "id": "radioactivity_concentration_of_138Cs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_138Cs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cs\" means the element \"cesium\" and \"138Cs\" is the isotope \"cesium-138\" with a half-life of 2.23e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_138Xe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_138Xe_in_air.json index 80a6bfde8..2cfb11b4c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_138Xe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_138Xe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_138Xe_in_air", + "id": "radioactivity_concentration_of_138Xe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_138Xe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Xe\" means the element \"xenon\" and \"138Xe\" is the isotope \"xenon-138\" with a half-life of 9.84e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_139Ba_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_139Ba_in_air.json index 6e6fb7d75..a1b8d259d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_139Ba_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_139Ba_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_139Ba_in_air", + "id": "radioactivity_concentration_of_139Ba_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_139Ba_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"139Ba\" is the isotope \"barium-139\" with a half-life of 5.77e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_13N_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_13N_in_air.json index 1616e9e01..0edf7ef2f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_13N_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_13N_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_13N_in_air", + "id": "radioactivity_concentration_of_13N_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_13N_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"N\" means the element \"nitrogen\" and \"13N\" is the isotope \"nitrogen-13\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_140Ba_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_140Ba_in_air.json index 007ffd581..6ab701f6d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_140Ba_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_140Ba_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_140Ba_in_air", + "id": "radioactivity_concentration_of_140Ba_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_140Ba_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ba\" means the element \"barium\" and \"140Ba\" is the isotope \"barium-140\" with a half-life of 1.28e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_140La_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_140La_in_air.json index b54c89ce4..9e0075130 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_140La_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_140La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_140La_in_air", + "id": "radioactivity_concentration_of_140La_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_140La_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"140La\" is the isotope \"lanthanum-140\" with a half-life of 1.76e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_141Ce_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_141Ce_in_air.json index a8053d4a7..70d06af5f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_141Ce_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_141Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_141Ce_in_air", + "id": "radioactivity_concentration_of_141Ce_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_141Ce_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"141Ce\" is the isotope \"cerium-141\" with a half-life of 3.30e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_141La_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_141La_in_air.json index d9ff64c41..dc36c30c2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_141La_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_141La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_141La_in_air", + "id": "radioactivity_concentration_of_141La_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_141La_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"141La\" is the isotope \"lanthanum-141\" with a half-life of 1.61e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_142Ce_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_142Ce_in_air.json index 724e2fc34..8fd6c0154 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_142Ce_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_142Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_142Ce_in_air", + "id": "radioactivity_concentration_of_142Ce_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_142Ce_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"142Ce\" is the isotope \"cerium-142\" with a half-life of 1.82e+19 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_142La_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_142La_in_air.json index d028b845f..2d08e620f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_142La_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_142La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_142La_in_air", + "id": "radioactivity_concentration_of_142La_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_142La_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"142La\" is the isotope \"lanthanum-142\" with a half-life of 6.42e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_142Pr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_142Pr_in_air.json index 3e4dd6b46..617a617b9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_142Pr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_142Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_142Pr_in_air", + "id": "radioactivity_concentration_of_142Pr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_142Pr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"142Pr\" is the isotope \"praseodymium-142\" with a half-life of 7.94e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_142mPr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_142mPr_in_air.json index b3738b11c..2ee7877c0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_142mPr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_142mPr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_142mPr_in_air", + "id": "radioactivity_concentration_of_142mPr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_142mPr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"142mPr\" is the metastable state of the isotope \"praseodymium-142\" with a half-life of 1.01e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_143Ce_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_143Ce_in_air.json index 798866f90..32dce7931 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_143Ce_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_143Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_143Ce_in_air", + "id": "radioactivity_concentration_of_143Ce_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_143Ce_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"143Ce\" is the isotope \"cerium-143\" with a half-life of 1.37e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_143La_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_143La_in_air.json index 096dd1614..fd73bf72d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_143La_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_143La_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_143La_in_air", + "id": "radioactivity_concentration_of_143La_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_143La_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"La\" means the element \"lanthanum\" and \"143La\" is the isotope \"lanthanum-143\" with a half-life of 9.72e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_143Pr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_143Pr_in_air.json index 4f00078c0..e33672943 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_143Pr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_143Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_143Pr_in_air", + "id": "radioactivity_concentration_of_143Pr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_143Pr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"143Pr\" is the isotope \"praseodymium-143\" with a half-life of 1.36e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_144Ce_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_144Ce_in_air.json index d0a1a99ae..fb87db0ee 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_144Ce_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_144Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_144Ce_in_air", + "id": "radioactivity_concentration_of_144Ce_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_144Ce_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"144Ce\" is the isotope \"cerium-144\" with a half-life of 2.84e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_144Nd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_144Nd_in_air.json index a652c2c3b..5b6540a0c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_144Nd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_144Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_144Nd_in_air", + "id": "radioactivity_concentration_of_144Nd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_144Nd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"144Nd\" is the isotope \"neodymium-144\" with a half-life of 7.64e+17 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_144Pr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_144Pr_in_air.json index 98e3c705f..c8ece55a1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_144Pr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_144Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_144Pr_in_air", + "id": "radioactivity_concentration_of_144Pr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_144Pr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"144Pr\" is the isotope \"praseodymium-144\" with a half-life of 1.20e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_144mPr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_144mPr_in_air.json index b9122dcc9..f7aab4429 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_144mPr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_144mPr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_144mPr_in_air", + "id": "radioactivity_concentration_of_144mPr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_144mPr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"144mPr\" is the metastable state of the isotope \"praseodymium-144\" with a half-life of 4.98e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_145Pr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_145Pr_in_air.json index 09135ceb9..b304aa5d5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_145Pr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_145Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_145Pr_in_air", + "id": "radioactivity_concentration_of_145Pr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_145Pr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"145Pr\" is the isotope \"praseodymium-145\" with a half-life of 2.49e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_146Ce_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_146Ce_in_air.json index 982824fe9..1a4a09090 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_146Ce_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_146Ce_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_146Ce_in_air", + "id": "radioactivity_concentration_of_146Ce_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_146Ce_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ce\" means the element \"cerium\" and \"146Ce\" is the isotope \"cerium-146\" with a half-life of 9.86e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_146Pr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_146Pr_in_air.json index 70be87d35..502976786 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_146Pr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_146Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_146Pr_in_air", + "id": "radioactivity_concentration_of_146Pr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_146Pr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"146Pr\" is the isotope \"praseodymium-146\" with a half-life of 1.68e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_147Nd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_147Nd_in_air.json index 4930e5712..aba5ab896 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_147Nd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_147Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_147Nd_in_air", + "id": "radioactivity_concentration_of_147Nd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_147Nd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"147Nd\" is the isotope \"neodymium-147\" with a half-life of 1.10e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_147Pm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_147Pm_in_air.json index 2722995ca..f7cf70cea 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_147Pm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_147Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_147Pm_in_air", + "id": "radioactivity_concentration_of_147Pm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_147Pm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"147Pm\" is the isotope \"promethium-147\" with a half-life of 9.57e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_147Pr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_147Pr_in_air.json index 9177aca18..1382b442b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_147Pr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_147Pr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_147Pr_in_air", + "id": "radioactivity_concentration_of_147Pr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_147Pr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pr\" means the element \"praseodymium\" and \"147Pr\" is the isotope \"praseodymium-147\" with a half-life of 8.33e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_147Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_147Sm_in_air.json index 91f7b437b..220b3b1e9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_147Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_147Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_147Sm_in_air", + "id": "radioactivity_concentration_of_147Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_147Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"147Sm\" is the isotope \"samarium-147\" with a half-life of 3.91e+13 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_148Pm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_148Pm_in_air.json index 9d83ad76a..be60f0aaf 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_148Pm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_148Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_148Pm_in_air", + "id": "radioactivity_concentration_of_148Pm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_148Pm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"148Pm\" is the isotope \"promethium-148\" with a half-life of 5.38e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_148Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_148Sm_in_air.json index 8da756d38..8281ec965 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_148Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_148Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_148Sm_in_air", + "id": "radioactivity_concentration_of_148Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_148Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"148Sm\" is the isotope \"samarium-148\" with a half-life of 2.92e+18 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_148mPm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_148mPm_in_air.json index d2ec66fdc..0ecae9716 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_148mPm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_148mPm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_148mPm_in_air", + "id": "radioactivity_concentration_of_148mPm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_148mPm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"148mPm\" is the metastable state of the isotope \"promethium-148\" with a half-life of 4.14e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_149Nd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_149Nd_in_air.json index 606040af4..c1581b5bc 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_149Nd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_149Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_149Nd_in_air", + "id": "radioactivity_concentration_of_149Nd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_149Nd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"149Nd\" is the isotope \"neodymium-149\" with a half-life of 7.23e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_149Pm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_149Pm_in_air.json index e8b32448d..21ab9a80f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_149Pm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_149Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_149Pm_in_air", + "id": "radioactivity_concentration_of_149Pm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_149Pm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"149Pm\" is the isotope \"promethium-149\" with a half-life of 2.21e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_149Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_149Sm_in_air.json index 6a5b5ce1a..89bbbe054 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_149Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_149Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_149Sm_in_air", + "id": "radioactivity_concentration_of_149Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_149Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"149Sm\" is the isotope \"samarium-149\" with a half-life of 3.65e+18 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_150Pm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_150Pm_in_air.json index 10d8c615c..c50b83a62 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_150Pm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_150Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_150Pm_in_air", + "id": "radioactivity_concentration_of_150Pm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_150Pm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"150Pm\" is the isotope \"promethium-150\" with a half-life of 1.12e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_151Nd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_151Nd_in_air.json index e9acc6170..1819de043 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_151Nd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_151Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_151Nd_in_air", + "id": "radioactivity_concentration_of_151Nd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_151Nd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"151Nd\" is the isotope \"neodymium-151\" with a half-life of 8.61e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_151Pm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_151Pm_in_air.json index a8551e211..9bd626d0b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_151Pm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_151Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_151Pm_in_air", + "id": "radioactivity_concentration_of_151Pm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_151Pm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"151Pm\" is the isotope \"promethium-151\" with a half-life of 1.18e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_151Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_151Sm_in_air.json index 9c8bd8fbd..c4446413d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_151Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_151Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_151Sm_in_air", + "id": "radioactivity_concentration_of_151Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_151Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"151Sm\" is the isotope \"samarium-151\" with a half-life of 3.40e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_152Nd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_152Nd_in_air.json index b4c758101..c98175fb3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_152Nd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_152Nd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_152Nd_in_air", + "id": "radioactivity_concentration_of_152Nd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_152Nd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nd\" means the element \"neodymium\" and \"152Nd\" is the isotope \"neodymium-152\" with a half-life of 7.94e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_152Pm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_152Pm_in_air.json index 1e4cf3d02..55d8a6a5d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_152Pm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_152Pm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_152Pm_in_air", + "id": "radioactivity_concentration_of_152Pm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_152Pm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"152Pm\" is the isotope \"promethium-152\" with a half-life of 2.84e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_152mPm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_152mPm_in_air.json index d16f8b837..810908411 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_152mPm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_152mPm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_152mPm_in_air", + "id": "radioactivity_concentration_of_152mPm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_152mPm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pm\" means the element \"promethium\" and \"152mPm\" is the metastable state of the isotope \"promethium-152\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_153Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_153Sm_in_air.json index 3f975138f..394d21e17 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_153Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_153Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_153Sm_in_air", + "id": "radioactivity_concentration_of_153Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_153Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"153Sm\" is the isotope \"samarium-153\" with a half-life of 1.94e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_154Eu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_154Eu_in_air.json index 20b9ec1a8..75bcaccf4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_154Eu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_154Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_154Eu_in_air", + "id": "radioactivity_concentration_of_154Eu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_154Eu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"154Eu\" is the isotope \"europium-154\" with a half-life of 3.13e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_155Eu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_155Eu_in_air.json index 82295d429..e01437075 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_155Eu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_155Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_155Eu_in_air", + "id": "radioactivity_concentration_of_155Eu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_155Eu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"155Eu\" is the isotope \"europium-155\" with a half-life of 1.75e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_155Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_155Sm_in_air.json index 5c8080356..15f59f213 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_155Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_155Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_155Sm_in_air", + "id": "radioactivity_concentration_of_155Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_155Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"155Sm\" is the isotope \"samarium-155\" with a half-life of 1.54e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_156Eu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_156Eu_in_air.json index 83bf912d5..b5c3be761 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_156Eu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_156Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_156Eu_in_air", + "id": "radioactivity_concentration_of_156Eu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_156Eu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"156Eu\" is the isotope \"europium-156\" with a half-life of 1.52e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_156Sm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_156Sm_in_air.json index a79deea81..9055a724d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_156Sm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_156Sm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_156Sm_in_air", + "id": "radioactivity_concentration_of_156Sm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_156Sm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sm\" means the element \"samarium\" and \"156Sm\" is the isotope \"samarium-156\" with a half-life of 3.91e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_157Eu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_157Eu_in_air.json index c7d07a81f..debb44010 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_157Eu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_157Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_157Eu_in_air", + "id": "radioactivity_concentration_of_157Eu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_157Eu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"157Eu\" is the isotope \"europium-157\" with a half-life of 6.32e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_158Eu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_158Eu_in_air.json index a99ec6964..c03598518 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_158Eu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_158Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_158Eu_in_air", + "id": "radioactivity_concentration_of_158Eu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_158Eu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"158Eu\" is the isotope \"europium-158\" with a half-life of 3.18e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_159Eu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_159Eu_in_air.json index 9833613f7..9ed9441f1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_159Eu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_159Eu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_159Eu_in_air", + "id": "radioactivity_concentration_of_159Eu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_159Eu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Eu\" means the element \"europium\" and \"159Eu\" is the isotope \"europium-159\" with a half-life of 1.26e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_159Gd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_159Gd_in_air.json index ade1aeb44..8eedd35a9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_159Gd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_159Gd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_159Gd_in_air", + "id": "radioactivity_concentration_of_159Gd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_159Gd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Gd\" means the element \"gadolinium\" and \"159Gd\" is the isotope \"gadolinium-159\" with a half-life of 7.71e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_15O_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_15O_in_air.json index c2dec35a9..c709b59a5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_15O_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_15O_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_15O_in_air", + "id": "radioactivity_concentration_of_15O_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_15O_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"O\" means the element \"oxygen\" and \"15O\" is the isotope \"oxygen-15\" with a half-life of 1.41e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_160Tb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_160Tb_in_air.json index 5437f9e3a..89e9dc32b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_160Tb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_160Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_160Tb_in_air", + "id": "radioactivity_concentration_of_160Tb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_160Tb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"160Tb\" is the isotope \"terbium-160\" with a half-life of 7.23e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_161Tb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_161Tb_in_air.json index 7eb28f53a..749b24db3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_161Tb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_161Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_161Tb_in_air", + "id": "radioactivity_concentration_of_161Tb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_161Tb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"161Tb\" is the isotope \"terbium-161\" with a half-life of 6.92e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_162Gd_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_162Gd_in_air.json index b2e654eb6..a74874126 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_162Gd_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_162Gd_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_162Gd_in_air", + "id": "radioactivity_concentration_of_162Gd_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_162Gd_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Gd\" means the element \"gadolinium\" and \"162Gd\" is the isotope \"gadolinium-162\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_162Tb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_162Tb_in_air.json index f1d80245f..6a79d5229 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_162Tb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_162Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_162Tb_in_air", + "id": "radioactivity_concentration_of_162Tb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_162Tb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"162Tb\" is the isotope \"terbium-162\" with a half-life of 5.18e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_162mTb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_162mTb_in_air.json index 70ba9eb31..7e99f50a5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_162mTb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_162mTb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_162mTb_in_air", + "id": "radioactivity_concentration_of_162mTb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_162mTb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"162mTb\" is the metastable state of the isotope \"terbium-162\" with a half-life of 9.30e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_163Tb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_163Tb_in_air.json index a0d677165..4d8911f21 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_163Tb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_163Tb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_163Tb_in_air", + "id": "radioactivity_concentration_of_163Tb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_163Tb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tb\" means the element \"terbium\" and \"163Tb\" is the isotope \"terbium-163\" with a half-life of 1.36e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_165Dy_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_165Dy_in_air.json index 9ac34781a..47f7d8a63 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_165Dy_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_165Dy_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_165Dy_in_air", + "id": "radioactivity_concentration_of_165Dy_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_165Dy_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Dy\" means the element \"dysprosium\" and \"165Dy\" is the isotope \"dysprosium-165\" with a half-life of 9.80e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_18F_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_18F_in_air.json index 9b68fbe1a..8c972ce4c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_18F_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_18F_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_18F_in_air", + "id": "radioactivity_concentration_of_18F_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_18F_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"F\" means the element \"fluorine\" and \"18F\" is the isotope \"fluorine-18\" with a half-life of 6.98e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_206Hg_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_206Hg_in_air.json index ecb867bdc..acf47c2d2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_206Hg_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_206Hg_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_206Hg_in_air", + "id": "radioactivity_concentration_of_206Hg_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_206Hg_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Hg\" means the element \"mercury\" and \"206Hg\" is the isotope \"mercury-206\" with a half-life of 5.57e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_206Tl_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_206Tl_in_air.json index d89c6672b..64174d0f6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_206Tl_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_206Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_206Tl_in_air", + "id": "radioactivity_concentration_of_206Tl_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_206Tl_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"206Tl\" is the isotope \"thallium-206\" with a half-life of 2.91e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_207Tl_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_207Tl_in_air.json index 649f7a31c..45cbb1682 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_207Tl_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_207Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_207Tl_in_air", + "id": "radioactivity_concentration_of_207Tl_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_207Tl_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"207Tl\" is the isotope \"thallium-207\" with a half-life of 3.33e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_207mPb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_207mPb_in_air.json index c799b1ee3..ba8ec2701 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_207mPb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_207mPb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_207mPb_in_air", + "id": "radioactivity_concentration_of_207mPb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_207mPb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"207mPb\" is the metastable state of the isotope \"lead-207\" with a half-life of 9.26e-06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_208Tl_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_208Tl_in_air.json index 3c9095090..57edff37b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_208Tl_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_208Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_208Tl_in_air", + "id": "radioactivity_concentration_of_208Tl_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_208Tl_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"208Tl\" is the isotope \"thallium-208\" with a half-life of 2.15e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_209Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_209Bi_in_air.json index 8a8782225..2dd76308b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_209Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_209Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_209Bi_in_air", + "id": "radioactivity_concentration_of_209Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_209Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"209Bi\" is the isotope \"bismuth-209\" with a half-life of 7.29e+20 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_209Pb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_209Pb_in_air.json index 3f55d0641..2250794d7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_209Pb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_209Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_209Pb_in_air", + "id": "radioactivity_concentration_of_209Pb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_209Pb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"209Pb\" is the isotope \"lead-209\" with a half-life of 1.38e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_209Tl_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_209Tl_in_air.json index f0a96c1cb..0d2d52412 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_209Tl_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_209Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_209Tl_in_air", + "id": "radioactivity_concentration_of_209Tl_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_209Tl_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"209Tl\" is the isotope \"thallium-209\" with a half-life of 1.53e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_210Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_210Bi_in_air.json index 5d012d43a..4375454a3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_210Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_210Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_210Bi_in_air", + "id": "radioactivity_concentration_of_210Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_210Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"210Bi\" is the isotope \"bismuth-210\" with a half-life of 5.01e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_210Pb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_210Pb_in_air.json index d0577656b..2a4d800a8 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_210Pb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_210Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_210Pb_in_air", + "id": "radioactivity_concentration_of_210Pb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_210Pb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"210Pb\" is the isotope \"lead-210\" with a half-life of 7.64e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_210Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_210Po_in_air.json index 4e2bbb8a2..c64e5f67b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_210Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_210Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_210Po_in_air", + "id": "radioactivity_concentration_of_210Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_210Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"210Po\" is the isotope \"polonium-210\" with a half-life of 1.38e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_210Tl_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_210Tl_in_air.json index 7e5846cdd..083e1f446 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_210Tl_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_210Tl_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_210Tl_in_air", + "id": "radioactivity_concentration_of_210Tl_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_210Tl_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tl\" means the element \"thallium\" and \"210Tl\" is the isotope \"thallium-210\" with a half-life of 9.02e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_211Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_211Bi_in_air.json index 6714b0add..7a566c99b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_211Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_211Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_211Bi_in_air", + "id": "radioactivity_concentration_of_211Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_211Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"211Bi\" is the isotope \"bismuth-211\" with a half-life of 1.49e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_211Pb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_211Pb_in_air.json index a6527837e..9dbf396eb 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_211Pb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_211Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_211Pb_in_air", + "id": "radioactivity_concentration_of_211Pb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_211Pb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"211Pb\" is the isotope \"lead-211\" with a half-life of 2.51e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_211Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_211Po_in_air.json index 8cdc740e6..3e4cc50f8 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_211Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_211Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_211Po_in_air", + "id": "radioactivity_concentration_of_211Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_211Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"211Po\" is the isotope \"polonium-211\" with a half-life of 6.03e-06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_212Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_212Bi_in_air.json index e4118009c..9db23f523 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_212Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_212Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_212Bi_in_air", + "id": "radioactivity_concentration_of_212Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_212Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"212Bi\" is the isotope \"bismuth-212\" with a half-life of 4.20e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_212Pb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_212Pb_in_air.json index a2bf1fcc7..8598b9e3e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_212Pb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_212Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_212Pb_in_air", + "id": "radioactivity_concentration_of_212Pb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_212Pb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"212Pb\" is the isotope \"lead-212\" with a half-life of 4.43e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_212Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_212Po_in_air.json index 2de9edad6..dc4340611 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_212Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_212Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_212Po_in_air", + "id": "radioactivity_concentration_of_212Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_212Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"212Po\" is the isotope \"polonium-212\" with a half-life of 3.52e-12 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_213Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_213Bi_in_air.json index f7a36f05e..cd541c804 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_213Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_213Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_213Bi_in_air", + "id": "radioactivity_concentration_of_213Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_213Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"213Bi\" is the isotope \"bismuth-213\" with a half-life of 3.26e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_213Pb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_213Pb_in_air.json index 856a15fdf..fe299e7e2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_213Pb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_213Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_213Pb_in_air", + "id": "radioactivity_concentration_of_213Pb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_213Pb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"213Pb\" is the isotope \"lead-213\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_213Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_213Po_in_air.json index f6b3eaa9a..42629b304 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_213Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_213Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_213Po_in_air", + "id": "radioactivity_concentration_of_213Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_213Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"213Po\" is the isotope \"polonium-213\" with a half-life of 4.86e-11 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_214Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_214Bi_in_air.json index 3bf7135a3..a6dd19f5f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_214Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_214Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_214Bi_in_air", + "id": "radioactivity_concentration_of_214Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_214Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"214Bi\" is the isotope \"bismuth-214\" with a half-life of 1.37e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_214Pb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_214Pb_in_air.json index 1f4bddab7..2b4c63801 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_214Pb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_214Pb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_214Pb_in_air", + "id": "radioactivity_concentration_of_214Pb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_214Pb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pb\" means the element \"lead\" and \"214Pb\" is the isotope \"lead-214\" with a half-life of 1.86e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_214Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_214Po_in_air.json index 9d1abaa1f..ea341a113 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_214Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_214Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_214Po_in_air", + "id": "radioactivity_concentration_of_214Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_214Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"214Po\" is the isotope \"polonium-214\" with a half-life of 1.90e-09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_215At_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_215At_in_air.json index 5c8946d56..70f36996c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_215At_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_215At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_215At_in_air", + "id": "radioactivity_concentration_of_215At_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_215At_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"215At\" is the isotope \"astatine-215\" with a half-life of 1.16e-09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_215Bi_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_215Bi_in_air.json index ce707232b..928dc2dbf 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_215Bi_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_215Bi_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_215Bi_in_air", + "id": "radioactivity_concentration_of_215Bi_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_215Bi_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bi\" means the element \"bismuth\" and \"215Bi\" is the isotope \"bismuth-215\" with a half-life of 4.86e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_215Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_215Po_in_air.json index fc330cc7f..26ec46b5e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_215Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_215Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_215Po_in_air", + "id": "radioactivity_concentration_of_215Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_215Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"215Po\" is the isotope \"polonium-215\" with a half-life of 2.06e-08 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_216At_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_216At_in_air.json index e55947b08..9d52789c1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_216At_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_216At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_216At_in_air", + "id": "radioactivity_concentration_of_216At_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_216At_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"216At\" is the isotope \"astatine-216\" with a half-life of 3.47e-09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_216Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_216Po_in_air.json index 90edc6211..fb2b62f52 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_216Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_216Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_216Po_in_air", + "id": "radioactivity_concentration_of_216Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_216Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"216Po\" is the isotope \"polonium-216\" with a half-life of 1.74e-06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_217At_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_217At_in_air.json index 1e3305255..e59a48d2a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_217At_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_217At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_217At_in_air", + "id": "radioactivity_concentration_of_217At_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_217At_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"217At\" is the isotope \"astatine-217\" with a half-life of 3.70e-07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_217Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_217Po_in_air.json index 91f982e60..4165a4c18 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_217Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_217Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_217Po_in_air", + "id": "radioactivity_concentration_of_217Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_217Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"217Po\" is the isotope \"polonium-217\" with a half-life of 1.16e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_218At_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_218At_in_air.json index 21b86d623..65e877578 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_218At_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_218At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_218At_in_air", + "id": "radioactivity_concentration_of_218At_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_218At_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"218At\" is the isotope \"astatine-218\" with a half-life of 2.31e-05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_218Po_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_218Po_in_air.json index 991973eca..95bd5d81e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_218Po_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_218Po_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_218Po_in_air", + "id": "radioactivity_concentration_of_218Po_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_218Po_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Po\" means the element \"polonium\" and \"218Po\" is the isotope \"polonium-218\" with a half-life of 2.12e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_218Rn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_218Rn_in_air.json index 5e5a8de3a..d3c54469e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_218Rn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_218Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_218Rn_in_air", + "id": "radioactivity_concentration_of_218Rn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_218Rn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"218Rn\" is the isotope \"radon-218\" with a half-life of 4.05e-07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_219At_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_219At_in_air.json index 743a00245..43397b07d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_219At_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_219At_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_219At_in_air", + "id": "radioactivity_concentration_of_219At_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_219At_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"At\" means the element \"astatine\" and \"219At\" is the isotope \"astatine-219\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_219Rn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_219Rn_in_air.json index 6388e5000..2070a1209 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_219Rn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_219Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_219Rn_in_air", + "id": "radioactivity_concentration_of_219Rn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_219Rn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"219Rn\" is the isotope \"radon-219\" with a half-life of 4.64e-05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_220Rn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_220Rn_in_air.json index 67a5334e5..ac260587e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_220Rn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_220Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_220Rn_in_air", + "id": "radioactivity_concentration_of_220Rn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_220Rn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"220Rn\" is the isotope \"radon-220\" with a half-life of 6.37e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_221Fr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_221Fr_in_air.json index 8bc24abfc..43cde6f61 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_221Fr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_221Fr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_221Fr_in_air", + "id": "radioactivity_concentration_of_221Fr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_221Fr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Fr\" means the element \"francium\" and \"221Fr\" is the isotope \"francium-221\" with a half-life of 3.33e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_221Rn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_221Rn_in_air.json index b347dbffc..835faba2c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_221Rn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_221Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_221Rn_in_air", + "id": "radioactivity_concentration_of_221Rn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_221Rn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"221Rn\" is the isotope \"radon-221\" with a half-life of 1.74e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_222Fr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_222Fr_in_air.json index b5d269c19..9ef42809d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_222Fr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_222Fr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_222Fr_in_air", + "id": "radioactivity_concentration_of_222Fr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_222Fr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Fr\" means the element \"francium\" and \"222Fr\" is the isotope \"francium-222\" with a half-life of 1.03e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_222Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_222Ra_in_air.json index a12a33ab8..153973032 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_222Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_222Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_222Ra_in_air", + "id": "radioactivity_concentration_of_222Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_222Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"222Ra\" is the isotope \"radium-222\" with a half-life of 4.41e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_222Rn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_222Rn_in_air.json index 10ad38cfd..999df371c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_222Rn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_222Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_222Rn_in_air", + "id": "radioactivity_concentration_of_222Rn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_222Rn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"222Rn\" is the isotope \"radon-222\" with a half-life of 3.82e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_223Fr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_223Fr_in_air.json index bf9686533..adfd7516b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_223Fr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_223Fr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_223Fr_in_air", + "id": "radioactivity_concentration_of_223Fr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_223Fr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Fr\" means the element \"francium\" and \"223Fr\" is the isotope \"francium-223\" with a half-life of 1.53e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_223Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_223Ra_in_air.json index bd1ba8692..95ed7491d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_223Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_223Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_223Ra_in_air", + "id": "radioactivity_concentration_of_223Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_223Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"223Ra\" is the isotope \"radium-223\" with a half-life of 1.14e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_223Rn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_223Rn_in_air.json index 86fb300fb..a53e99dd5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_223Rn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_223Rn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_223Rn_in_air", + "id": "radioactivity_concentration_of_223Rn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_223Rn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rn\" means the element \"radon\" and \"223Rn\" is the isotope \"radon-223\" with a half-life of 2.98e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_224Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_224Ra_in_air.json index a327b80b2..27b88ed0b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_224Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_224Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_224Ra_in_air", + "id": "radioactivity_concentration_of_224Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_224Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"224Ra\" is the isotope \"radium-224\" with a half-life of 3.65e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_225Ac_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_225Ac_in_air.json index 1c64986b8..6b52e8b0c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_225Ac_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_225Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_225Ac_in_air", + "id": "radioactivity_concentration_of_225Ac_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_225Ac_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"225Ac\" is the isotope \"actinium-225\" with a half-life of 1.00e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_225Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_225Ra_in_air.json index e19d73682..0e0cc08bc 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_225Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_225Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_225Ra_in_air", + "id": "radioactivity_concentration_of_225Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_225Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"225Ra\" is the isotope \"radium-225\" with a half-life of 1.48e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_226Ac_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_226Ac_in_air.json index d8bf3beb4..84aa88f01 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_226Ac_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_226Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_226Ac_in_air", + "id": "radioactivity_concentration_of_226Ac_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_226Ac_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"226Ac\" is the isotope \"actinium-226\" with a half-life of 1.21e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_226Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_226Ra_in_air.json index 7e6e35a7a..581e1f620 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_226Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_226Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_226Ra_in_air", + "id": "radioactivity_concentration_of_226Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_226Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"226Ra\" is the isotope \"radium-226\" with a half-life of 5.86e+05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_226Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_226Th_in_air.json index 8b30e94fa..c48cd0bfd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_226Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_226Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_226Th_in_air", + "id": "radioactivity_concentration_of_226Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_226Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"226Th\" is the isotope \"thorium-226\" with a half-life of 2.15e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_227Ac_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_227Ac_in_air.json index d86e9003c..9fe749d3d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_227Ac_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_227Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_227Ac_in_air", + "id": "radioactivity_concentration_of_227Ac_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_227Ac_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"227Ac\" is the isotope \"actinium-227\" with a half-life of 7.87e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_227Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_227Ra_in_air.json index 862d2a04a..312449b6f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_227Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_227Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_227Ra_in_air", + "id": "radioactivity_concentration_of_227Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_227Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"227Ra\" is the isotope \"radium-227\" with a half-life of 2.87e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_227Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_227Th_in_air.json index d71b2ffa9..fcd045715 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_227Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_227Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_227Th_in_air", + "id": "radioactivity_concentration_of_227Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_227Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"227Th\" is the isotope \"thorium-227\" with a half-life of 1.82e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_228Ac_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_228Ac_in_air.json index 4ce509b23..d19109d77 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_228Ac_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_228Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_228Ac_in_air", + "id": "radioactivity_concentration_of_228Ac_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_228Ac_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"228Ac\" is the isotope \"actinium-228\" with a half-life of 2.55e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_228Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_228Ra_in_air.json index 81eeb55e8..8e4ddfc46 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_228Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_228Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_228Ra_in_air", + "id": "radioactivity_concentration_of_228Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_228Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"228Ra\" is the isotope \"radium-228\" with a half-life of 2.45e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_228Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_228Th_in_air.json index e300b5df4..3e689bb2d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_228Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_228Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_228Th_in_air", + "id": "radioactivity_concentration_of_228Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_228Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"228Th\" is the isotope \"thorium-228\" with a half-life of 6.98e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_229Ac_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_229Ac_in_air.json index e5ff86473..594cd4d57 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_229Ac_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_229Ac_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_229Ac_in_air", + "id": "radioactivity_concentration_of_229Ac_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_229Ac_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ac\" means the element \"actinium\" and \"229Ac\" is the isotope \"actinium-229\" with a half-life of 4.58e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_229Ra_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_229Ra_in_air.json index 0c0d70fe2..3bea47edd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_229Ra_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_229Ra_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_229Ra_in_air", + "id": "radioactivity_concentration_of_229Ra_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_229Ra_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ra\" means the element \"radium\" and \"229Ra\" is the isotope \"radium-229\" with a half-life of 1.16e-17 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_229Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_229Th_in_air.json index de9889735..1c57bf6ab 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_229Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_229Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_229Th_in_air", + "id": "radioactivity_concentration_of_229Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_229Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"229Th\" is the isotope \"thorium-229\" with a half-life of 2.68e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_230Pa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_230Pa_in_air.json index 3b498e777..4a117af71 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_230Pa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_230Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_230Pa_in_air", + "id": "radioactivity_concentration_of_230Pa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_230Pa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"230Pa\" is the isotope \"protactinium-230\" with a half-life of 1.77e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_230Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_230Th_in_air.json index 9425409f7..986131a30 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_230Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_230Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_230Th_in_air", + "id": "radioactivity_concentration_of_230Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_230Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"230Th\" is the isotope \"thorium-230\" with a half-life of 2.92e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_230U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_230U_in_air.json index 44a4bca3a..f1c2b4a34 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_230U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_230U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_230U_in_air", + "id": "radioactivity_concentration_of_230U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_230U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"230U\" is the isotope \"uranium-230\" with a half-life of 2.08e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_231Pa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_231Pa_in_air.json index 612ebd685..bee23eb37 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_231Pa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_231Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_231Pa_in_air", + "id": "radioactivity_concentration_of_231Pa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_231Pa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"231Pa\" is the isotope \"protactinium-231\" with a half-life of 1.19e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_231Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_231Th_in_air.json index 276dd4c77..fe6b1bb56 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_231Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_231Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_231Th_in_air", + "id": "radioactivity_concentration_of_231Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_231Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"231Th\" is the isotope \"thorium-231\" with a half-life of 1.06e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_231U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_231U_in_air.json index 2942bdaae..4b13c0f1a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_231U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_231U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_231U_in_air", + "id": "radioactivity_concentration_of_231U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_231U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"231U\" is the isotope \"uranium-231\" with a half-life of 4.29e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_232Pa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_232Pa_in_air.json index af39594d9..4a4ec9dac 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_232Pa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_232Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_232Pa_in_air", + "id": "radioactivity_concentration_of_232Pa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_232Pa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"232Pa\" is the isotope \"protactinium-232\" with a half-life of 1.31e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_232Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_232Th_in_air.json index e309a0ae4..8925c32ae 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_232Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_232Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_232Th_in_air", + "id": "radioactivity_concentration_of_232Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_232Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"232Th\" is the isotope \"thorium-232\" with a half-life of 5.14e+12 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_232U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_232U_in_air.json index c949c4516..fb986ccfb 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_232U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_232U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_232U_in_air", + "id": "radioactivity_concentration_of_232U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_232U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"232U\" is the isotope \"uranium-232\" with a half-life of 2.63e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_233Pa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_233Pa_in_air.json index f00e9700a..6b365bc5d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_233Pa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_233Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_233Pa_in_air", + "id": "radioactivity_concentration_of_233Pa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_233Pa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"233Pa\" is the isotope \"protactinium-233\" with a half-life of 2.70e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_233Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_233Th_in_air.json index b836dce40..c80e786be 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_233Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_233Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_233Th_in_air", + "id": "radioactivity_concentration_of_233Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_233Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"233Th\" is the isotope \"thorium-233\" with a half-life of 1.54e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_233U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_233U_in_air.json index 157c30561..30cf94425 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_233U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_233U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_233U_in_air", + "id": "radioactivity_concentration_of_233U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_233U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"233U\" is the isotope \"uranium-233\" with a half-life of 5.90e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_234Pa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_234Pa_in_air.json index dab733b5b..8eeb12b26 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_234Pa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_234Pa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_234Pa_in_air", + "id": "radioactivity_concentration_of_234Pa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_234Pa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"234Pa\" is the isotope \"protactinium-234\" with a half-life of 2.81e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_234Th_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_234Th_in_air.json index b28c579c7..b67eae53e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_234Th_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_234Th_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_234Th_in_air", + "id": "radioactivity_concentration_of_234Th_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_234Th_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Th\" means the element \"thorium\" and \"234Th\" is the isotope \"thorium-234\" with a half-life of 2.41e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_234U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_234U_in_air.json index 59c6f835a..1b7dc39aa 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_234U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_234U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_234U_in_air", + "id": "radioactivity_concentration_of_234U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_234U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"234U\" is the isotope \"uranium-234\" with a half-life of 9.02e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_234mPa_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_234mPa_in_air.json index b98f0040d..bc11d9332 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_234mPa_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_234mPa_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_234mPa_in_air", + "id": "radioactivity_concentration_of_234mPa_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_234mPa_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pa\" means the element \"protactinium\" and \"234mPa\" is the metastable state of the isotope \"protactinium-234\" with a half-life of 8.13e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_235Np_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_235Np_in_air.json index 02860efda..2c2932753 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_235Np_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_235Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_235Np_in_air", + "id": "radioactivity_concentration_of_235Np_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_235Np_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"235Np\" is the isotope \"neptunium-235\" with a half-life of 4.09e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_235Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_235Pu_in_air.json index a85ee9b5d..9c2720480 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_235Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_235Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_235Pu_in_air", + "id": "radioactivity_concentration_of_235Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_235Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"235Pu\" is the isotope \"plutonium-235\" with a half-life of 1.81e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_235U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_235U_in_air.json index 25eb28d3e..f71a1aeb4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_235U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_235U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_235U_in_air", + "id": "radioactivity_concentration_of_235U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_235U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"235U\" is the isotope \"uranium-235\" with a half-life of 2.60e+11 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_236Np_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_236Np_in_air.json index d3977446c..1be78e1a1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_236Np_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_236Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_236Np_in_air", + "id": "radioactivity_concentration_of_236Np_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_236Np_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"236Np\" is the isotope \"neptunium-236\" with a half-life of 9.17e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_236Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_236Pu_in_air.json index 293765a4c..bbb14d2f1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_236Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_236Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_236Pu_in_air", + "id": "radioactivity_concentration_of_236Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_236Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"236Pu\" is the isotope \"plutonium-236\" with a half-life of 1.04e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_236U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_236U_in_air.json index 351f26985..794be2441 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_236U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_236U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_236U_in_air", + "id": "radioactivity_concentration_of_236U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_236U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"236U\" is the isotope \"uranium-236\" with a half-life of 8.73e+09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_236mNp_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_236mNp_in_air.json index 0627fa97d..3ba476687 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_236mNp_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_236mNp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_236mNp_in_air", + "id": "radioactivity_concentration_of_236mNp_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_236mNp_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"236mNp\" is the metastable state of the isotope \"neptunium-236\" with a half-life of 4.72e+10 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_237Np_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_237Np_in_air.json index c670508dd..d8f29bae5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_237Np_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_237Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_237Np_in_air", + "id": "radioactivity_concentration_of_237Np_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_237Np_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"237Np\" is the isotope \"neptunium-237\" with a half-life of 7.79e+08 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_237Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_237Pu_in_air.json index f9b1a418c..3be4ce4e9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_237Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_237Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_237Pu_in_air", + "id": "radioactivity_concentration_of_237Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_237Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"237Pu\" is the isotope \"plutonium-237\" with a half-life of 4.56e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_237U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_237U_in_air.json index ba82ba6b2..a67f92b69 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_237U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_237U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_237U_in_air", + "id": "radioactivity_concentration_of_237U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_237U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"237U\" is the isotope \"uranium-237\" with a half-life of 6.74e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_238Np_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_238Np_in_air.json index 5294e690f..e0b641b7d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_238Np_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_238Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_238Np_in_air", + "id": "radioactivity_concentration_of_238Np_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_238Np_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"238Np\" is the isotope \"neptunium-238\" with a half-life of 2.10e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_238Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_238Pu_in_air.json index c44bd2a36..08a610e9b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_238Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_238Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_238Pu_in_air", + "id": "radioactivity_concentration_of_238Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_238Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"238Pu\" is the isotope \"plutonium-238\" with a half-life of 3.15e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_238U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_238U_in_air.json index 69131b1c4..f4f6dcce3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_238U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_238U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_238U_in_air", + "id": "radioactivity_concentration_of_238U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_238U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"238U\" is the isotope \"uranium-238\" with a half-life of 1.65e+12 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_239Np_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_239Np_in_air.json index 731ed3934..b49a80c17 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_239Np_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_239Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_239Np_in_air", + "id": "radioactivity_concentration_of_239Np_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_239Np_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"239Np\" is the isotope \"neptunium-239\" with a half-life of 2.35e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_239Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_239Pu_in_air.json index a51cde012..2a9f5c5bd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_239Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_239Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_239Pu_in_air", + "id": "radioactivity_concentration_of_239Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_239Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"239Pu\" is the isotope \"plutonium-239\" with a half-life of 8.91e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_239U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_239U_in_air.json index cb8086c2e..46b97a927 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_239U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_239U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_239U_in_air", + "id": "radioactivity_concentration_of_239U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_239U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"239U\" is the isotope \"uranium-239\" with a half-life of 1.63e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_240Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_240Am_in_air.json index 7926f09c1..ab44953eb 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_240Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_240Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_240Am_in_air", + "id": "radioactivity_concentration_of_240Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_240Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"240Am\" is the isotope \"americium-240\" with a half-life of 2.12e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_240Np_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_240Np_in_air.json index 455b29801..3da6c8a24 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_240Np_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_240Np_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_240Np_in_air", + "id": "radioactivity_concentration_of_240Np_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_240Np_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"240Np\" is the isotope \"neptunium-240\" with a half-life of 4.38e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_240Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_240Pu_in_air.json index 3ab948bf6..7b1b376c2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_240Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_240Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_240Pu_in_air", + "id": "radioactivity_concentration_of_240Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_240Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"240Pu\" is the isotope \"plutonium-240\" with a half-life of 2.40e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_240U_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_240U_in_air.json index 9596c2a2a..b9267ae1e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_240U_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_240U_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_240U_in_air", + "id": "radioactivity_concentration_of_240U_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_240U_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"U\" means the element \"uranium\" and \"240U\" is the isotope \"uranium-240\" with a half-life of 5.99e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_240mNp_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_240mNp_in_air.json index 360e5d520..9ebf9a307 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_240mNp_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_240mNp_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_240mNp_in_air", + "id": "radioactivity_concentration_of_240mNp_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_240mNp_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Np\" means the element \"neptunium\" and \"240mNp\" is the metastable state of the isotope \"neptunium-240\" with a half-life of 5.08e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_241Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_241Am_in_air.json index 4cef4b91d..9f2dde4a4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_241Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_241Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_241Am_in_air", + "id": "radioactivity_concentration_of_241Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_241Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"241Am\" is the isotope \"americium-241\" with a half-life of 1.67e+05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_241Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_241Cm_in_air.json index a9e797441..1a122d049 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_241Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_241Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_241Cm_in_air", + "id": "radioactivity_concentration_of_241Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_241Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"241Cm\" is the isotope \"curium-241\" with a half-life of 3.50e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_241Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_241Pu_in_air.json index 06a8dd82f..38d08e5ed 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_241Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_241Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_241Pu_in_air", + "id": "radioactivity_concentration_of_241Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_241Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"241Pu\" is the isotope \"plutonium-241\" with a half-life of 4.83e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_242Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_242Am_in_air.json index c435c4ad3..7cf9efbca 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_242Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_242Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_242Am_in_air", + "id": "radioactivity_concentration_of_242Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_242Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"242Am\" is the isotope \"americium-242\" with a half-life of 6.69e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_242Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_242Cm_in_air.json index ac9c80c5f..0b31fda16 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_242Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_242Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_242Cm_in_air", + "id": "radioactivity_concentration_of_242Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_242Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"242Cm\" is the isotope \"curium-242\" with a half-life of 1.63e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_242Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_242Pu_in_air.json index 48f13672a..55bf343be 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_242Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_242Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_242Pu_in_air", + "id": "radioactivity_concentration_of_242Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_242Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"242Pu\" is the isotope \"plutonium-242\" with a half-life of 1.38e+08 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_242m1Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_242m1Am_in_air.json index b397794e3..a7f3a9770 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_242m1Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_242m1Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_242m1Am_in_air", + "id": "radioactivity_concentration_of_242m1Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_242m1Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"242m1Am\" is the metastable state of the isotope \"americium-242\" with a half-life of 5.53e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_242m2Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_242m2Am_in_air.json index a49381f30..95fb46249 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_242m2Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_242m2Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_242m2Am_in_air", + "id": "radioactivity_concentration_of_242m2Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_242m2Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"242m2Am\" is the metastable state of the isotope \"americium-242\" with a half-life of 1.62e-07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_243Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_243Am_in_air.json index 3655a3be4..439f2d19f 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_243Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_243Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_243Am_in_air", + "id": "radioactivity_concentration_of_243Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_243Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"243Am\" is the isotope \"americium-243\" with a half-life of 2.91e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_243Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_243Cm_in_air.json index 2bdff1e97..8c8befa52 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_243Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_243Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_243Cm_in_air", + "id": "radioactivity_concentration_of_243Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_243Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"243Cm\" is the isotope \"curium-243\" with a half-life of 1.17e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_243Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_243Pu_in_air.json index 9b7801840..f4ea9fc71 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_243Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_243Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_243Pu_in_air", + "id": "radioactivity_concentration_of_243Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_243Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"243Pu\" is the isotope \"plutonium-243\" with a half-life of 2.07e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_244Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_244Am_in_air.json index acdd32afd..381f10370 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_244Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_244Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_244Am_in_air", + "id": "radioactivity_concentration_of_244Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_244Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"244Am\" is the isotope \"americium-244\" with a half-life of 4.20e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_244Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_244Cm_in_air.json index 2b8795926..2a0f52508 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_244Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_244Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_244Cm_in_air", + "id": "radioactivity_concentration_of_244Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_244Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"244Cm\" is the isotope \"curium-244\" with a half-life of 6.42e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_244Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_244Pu_in_air.json index 6d934a20c..7d27f3475 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_244Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_244Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_244Pu_in_air", + "id": "radioactivity_concentration_of_244Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_244Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"244Pu\" is the isotope \"plutonium-244\" with a half-life of 2.92e+10 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_244mAm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_244mAm_in_air.json index 767a49996..2c6ffb34e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_244mAm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_244mAm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_244mAm_in_air", + "id": "radioactivity_concentration_of_244mAm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_244mAm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"244mAm\" is the metastable state of the isotope \"americium-244\" with a half-life of 1.81e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_245Am_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_245Am_in_air.json index 01ef6fdd9..534241ee6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_245Am_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_245Am_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_245Am_in_air", + "id": "radioactivity_concentration_of_245Am_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_245Am_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Am\" means the element \"americium\" and \"245Am\" is the isotope \"americium-245\" with a half-life of 8.75e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_245Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_245Cm_in_air.json index 7cbd755bf..88a6ed2a4 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_245Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_245Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_245Cm_in_air", + "id": "radioactivity_concentration_of_245Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_245Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"245Cm\" is the isotope \"curium-245\" with a half-life of 3.40e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_245Pu_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_245Pu_in_air.json index 8d500d25d..cf14169da 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_245Pu_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_245Pu_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_245Pu_in_air", + "id": "radioactivity_concentration_of_245Pu_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_245Pu_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Pu\" means the element \"plutonium\" and \"245Pu\" is the isotope \"plutonium-245\" with a half-life of 4.16e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_246Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_246Cm_in_air.json index f3d36cd4f..1b2803cb1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_246Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_246Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_246Cm_in_air", + "id": "radioactivity_concentration_of_246Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_246Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"246Cm\" is the isotope \"curium-246\" with a half-life of 2.01e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_247Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_247Cm_in_air.json index 35417a9f2..38c8061da 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_247Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_247Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_247Cm_in_air", + "id": "radioactivity_concentration_of_247Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_247Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"247Cm\" is the isotope \"curium-247\" with a half-life of 5.86e+09 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_248Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_248Cm_in_air.json index c7bf8bce1..b0a506864 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_248Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_248Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_248Cm_in_air", + "id": "radioactivity_concentration_of_248Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_248Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"248Cm\" is the isotope \"curium-248\" with a half-life of 1.72e+08 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_249Bk_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_249Bk_in_air.json index f485c1c30..58817a2fb 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_249Bk_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_249Bk_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_249Bk_in_air", + "id": "radioactivity_concentration_of_249Bk_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_249Bk_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bk\" means the element \"berkelium\" and \"249Bk\" is the isotope \"berkelium-249\" with a half-life of 3.15e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_249Cf_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_249Cf_in_air.json index 26a8243f0..fe9e5b473 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_249Cf_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_249Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_249Cf_in_air", + "id": "radioactivity_concentration_of_249Cf_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_249Cf_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"249Cf\" is the isotope \"californium-249\" with a half-life of 1.32e+05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_249Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_249Cm_in_air.json index 3620b7d67..d39d23752 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_249Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_249Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_249Cm_in_air", + "id": "radioactivity_concentration_of_249Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_249Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"249Cm\" is the isotope \"curium-249\" with a half-life of 4.43e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_24Na_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_24Na_in_air.json index 2d6c2dd3a..577652876 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_24Na_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_24Na_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_24Na_in_air", + "id": "radioactivity_concentration_of_24Na_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_24Na_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Na\" means the element \"sodium\" and \"24Na\" is the isotope \"sodium-24\" with a half-life of 6.27e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_250Bk_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_250Bk_in_air.json index 5487715cf..bdd5c423e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_250Bk_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_250Bk_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_250Bk_in_air", + "id": "radioactivity_concentration_of_250Bk_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_250Bk_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Bk\" means the element \"berkelium\" and \"250Bk\" is the isotope \"berkelium-250\" with a half-life of 1.34e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_250Cf_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_250Cf_in_air.json index 2d0704cc4..9bbe910b7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_250Cf_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_250Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_250Cf_in_air", + "id": "radioactivity_concentration_of_250Cf_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_250Cf_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"250Cf\" is the isotope \"californium-250\" with a half-life of 4.75e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_250Cm_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_250Cm_in_air.json index fdc2a7a84..642756c8e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_250Cm_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_250Cm_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_250Cm_in_air", + "id": "radioactivity_concentration_of_250Cm_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_250Cm_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cm\" means the element \"curium\" and \"250Cm\" is the isotope \"curium-250\" with a half-life of 2.52e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_251Cf_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_251Cf_in_air.json index 44f6ff809..39521fcf3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_251Cf_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_251Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_251Cf_in_air", + "id": "radioactivity_concentration_of_251Cf_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_251Cf_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"251Cf\" is the isotope \"californium-251\" with a half-life of 2.92e+05 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_252Cf_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_252Cf_in_air.json index 61031db34..c56c36d1c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_252Cf_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_252Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_252Cf_in_air", + "id": "radioactivity_concentration_of_252Cf_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_252Cf_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"252Cf\" is the isotope \"californium-252\" with a half-life of 9.68e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_253Cf_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_253Cf_in_air.json index 047f7e1fd..3902e97b0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_253Cf_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_253Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_253Cf_in_air", + "id": "radioactivity_concentration_of_253Cf_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_253Cf_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"253Cf\" is the isotope \"californium-253\" with a half-life of 1.76e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_253Es_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_253Es_in_air.json index 763eefd54..e47d4626d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_253Es_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_253Es_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_253Es_in_air", + "id": "radioactivity_concentration_of_253Es_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_253Es_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"253Es\" is the isotope \"einsteinium-253\" with a half-life of 2.05e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_254Cf_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_254Cf_in_air.json index b613150fc..97b98d9e9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_254Cf_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_254Cf_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_254Cf_in_air", + "id": "radioactivity_concentration_of_254Cf_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_254Cf_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Cf\" means the element \"californium\" and \"254Cf\" is the isotope \"californium-254\" with a half-life of 6.03e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_254Es_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_254Es_in_air.json index 25f285fc8..4766d9d43 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_254Es_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_254Es_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_254Es_in_air", + "id": "radioactivity_concentration_of_254Es_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_254Es_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"254Es\" is the isotope \"einsteinium-254\" with a half-life of 2.76e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_254mEs_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_254mEs_in_air.json index 57d191a74..c751d4eb1 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_254mEs_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_254mEs_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_254mEs_in_air", + "id": "radioactivity_concentration_of_254mEs_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_254mEs_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"254mEs\" is the metastable state of the isotope \"einsteinium-254\" with a half-life of 1.63e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_255Es_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_255Es_in_air.json index 576052135..7d08a2a44 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_255Es_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_255Es_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_255Es_in_air", + "id": "radioactivity_concentration_of_255Es_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_255Es_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Es\" means the element \"einsteinium\" and \"255Es\" is the isotope \"einsteinium-255\" with a half-life of 3.84e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_3H_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_3H_in_air.json index 82baa6104..aa5caad58 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_3H_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_3H_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_3H_in_air", + "id": "radioactivity_concentration_of_3H_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_3H_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"H\" means the element \"hydrogen\" and \"3H\" is the isotope \"hydrogen-3\" with a half-life of 4.51e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_41Ar_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_41Ar_in_air.json index 2f7e4d4f6..741d0f0e5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_41Ar_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_41Ar_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_41Ar_in_air", + "id": "radioactivity_concentration_of_41Ar_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_41Ar_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ar\" means the element \"argon\" and \"41Ar\" is the isotope \"argon-41\" with a half-life of 7.64e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_54Mn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_54Mn_in_air.json index bcfb6a13a..5bcab1645 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_54Mn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_54Mn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_54Mn_in_air", + "id": "radioactivity_concentration_of_54Mn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_54Mn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mn\" means the element \"manganese\" and \"54Mn\" is the isotope \"manganese-54\" with a half-life of 3.12e+02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_58Co_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_58Co_in_air.json index f94843c44..9d3257095 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_58Co_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_58Co_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_58Co_in_air", + "id": "radioactivity_concentration_of_58Co_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_58Co_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Co\" means the element \"cobalt\" and \"58Co\" is the isotope \"cobalt-58\" with a half-life of 7.10e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_60Co_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_60Co_in_air.json index 46288032d..c4cac27cd 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_60Co_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_60Co_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_60Co_in_air", + "id": "radioactivity_concentration_of_60Co_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_60Co_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Co\" means the element \"cobalt\" and \"60Co\" is the isotope \"cobalt-60\" with a half-life of 1.93e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_72Ga_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_72Ga_in_air.json index 1e478cbe3..9fdd50e4b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_72Ga_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_72Ga_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_72Ga_in_air", + "id": "radioactivity_concentration_of_72Ga_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_72Ga_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ga\" means the element \"gallium\" and \"72Ga\" is the isotope \"gallium-72\" with a half-life of 5.86e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_72Zn_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_72Zn_in_air.json index 64cdcfde9..ebcee07f0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_72Zn_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_72Zn_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_72Zn_in_air", + "id": "radioactivity_concentration_of_72Zn_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_72Zn_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zn\" means the element \"zinc\" and \"72Zn\" is the isotope \"zinc-72\" with a half-life of 1.94e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_73Ga_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_73Ga_in_air.json index c4a8fa460..684fd531a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_73Ga_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_73Ga_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_73Ga_in_air", + "id": "radioactivity_concentration_of_73Ga_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_73Ga_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ga\" means the element \"gallium\" and \"73Ga\" is the isotope \"gallium-73\" with a half-life of 2.03e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_75Ge_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_75Ge_in_air.json index 0101d850b..6c1c60c73 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_75Ge_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_75Ge_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_75Ge_in_air", + "id": "radioactivity_concentration_of_75Ge_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_75Ge_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"75Ge\" is the isotope \"germanium-75\" with a half-life of 5.73e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_77As_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_77As_in_air.json index c92b791bd..c37032214 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_77As_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_77As_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_77As_in_air", + "id": "radioactivity_concentration_of_77As_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_77As_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"As\" means the element \"arsenic\" and \"77As\" is the isotope \"arsenic-77\" with a half-life of 1.62e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_77Ge_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_77Ge_in_air.json index 498ae129c..7e3270f60 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_77Ge_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_77Ge_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_77Ge_in_air", + "id": "radioactivity_concentration_of_77Ge_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_77Ge_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"77Ge\" is the isotope \"germanium-77\" with a half-life of 4.72e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_77mGe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_77mGe_in_air.json index 1a581d177..e27f177cf 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_77mGe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_77mGe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_77mGe_in_air", + "id": "radioactivity_concentration_of_77mGe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_77mGe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"77mGe\" is the metastable state of the isotope \"germanium-77\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_78As_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_78As_in_air.json index c75dc10f2..144cf145c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_78As_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_78As_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_78As_in_air", + "id": "radioactivity_concentration_of_78As_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_78As_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"As\" means the element \"arsenic\" and \"78As\" is the isotope \"arsenic-78\" with a half-life of 6.32e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_78Ge_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_78Ge_in_air.json index 6c63e0090..3fefc5618 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_78Ge_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_78Ge_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_78Ge_in_air", + "id": "radioactivity_concentration_of_78Ge_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_78Ge_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Ge\" means the element \"germanium\" and \"78Ge\" is the isotope \"germanium-78\" with a half-life of 6.03e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_79Se_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_79Se_in_air.json index 746f64617..d910ba1d7 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_79Se_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_79Se_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_79Se_in_air", + "id": "radioactivity_concentration_of_79Se_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_79Se_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"79Se\" is the isotope \"selenium-79\" with a half-life of 2.37e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_81Se_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_81Se_in_air.json index 02397a188..b70763ee0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_81Se_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_81Se_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_81Se_in_air", + "id": "radioactivity_concentration_of_81Se_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_81Se_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"81Se\" is the isotope \"selenium-81\" with a half-life of 1.28e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_81mSe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_81mSe_in_air.json index 75f9fc863..6a74f50d6 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_81mSe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_81mSe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_81mSe_in_air", + "id": "radioactivity_concentration_of_81mSe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_81mSe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"81mSe\" is the metastable state of the isotope \"selenium-81\" with a half-life of 3.97e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_82Br_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_82Br_in_air.json index ca4ca4cc1..819d1d0ff 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_82Br_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_82Br_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_82Br_in_air", + "id": "radioactivity_concentration_of_82Br_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_82Br_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"82Br\" is the isotope \"bromine-82\" with a half-life of 1.47e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_82mBr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_82mBr_in_air.json index d3e773e71..c2311d881 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_82mBr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_82mBr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_82mBr_in_air", + "id": "radioactivity_concentration_of_82mBr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_82mBr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"82mBr\" is the metastable state of the isotope \"bromine-82\" with a half-life of 4.24e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_83Br_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_83Br_in_air.json index 741daacd2..db0c50ddf 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_83Br_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_83Br_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_83Br_in_air", + "id": "radioactivity_concentration_of_83Br_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_83Br_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"83Br\" is the isotope \"bromine-83\" with a half-life of 1.00e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_83Se_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_83Se_in_air.json index f091a6927..2179ee60d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_83Se_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_83Se_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_83Se_in_air", + "id": "radioactivity_concentration_of_83Se_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_83Se_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"83Se\" is the isotope \"selenium-83\" with a half-life of 1.56e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_83mKr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_83mKr_in_air.json index 8a3b98f3d..5c9347e58 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_83mKr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_83mKr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_83mKr_in_air", + "id": "radioactivity_concentration_of_83mKr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_83mKr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"83mKr\" is the metastable state of the isotope \"krypton-83\" with a half-life of 7.71e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_83mSe_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_83mSe_in_air.json index 462c97faa..92753cce2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_83mSe_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_83mSe_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_83mSe_in_air", + "id": "radioactivity_concentration_of_83mSe_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_83mSe_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Se\" means the element \"selenium\" and \"83mSe\" is the metastable state of the isotope \"selenium-83\" with a half-life of 8.10e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_84Br_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_84Br_in_air.json index 795b43b03..2a434f794 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_84Br_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_84Br_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_84Br_in_air", + "id": "radioactivity_concentration_of_84Br_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_84Br_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"84Br\" is the isotope \"bromine-84\" with a half-life of 2.21e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_84mBr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_84mBr_in_air.json index c30621cae..01f7350a3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_84mBr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_84mBr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_84mBr_in_air", + "id": "radioactivity_concentration_of_84mBr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_84mBr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Br\" means the element \"bromine\" and \"84mBr\" is the metastable state of the isotope \"bromine-84\" with a half-life of 4.16e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_85Kr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_85Kr_in_air.json index 035aa5a6a..4cbcce003 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_85Kr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_85Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_85Kr_in_air", + "id": "radioactivity_concentration_of_85Kr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_85Kr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"85Kr\" is the isotope \"krypton-85\" with a half-life of 3.95e+03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_85mKr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_85mKr_in_air.json index 549464106..fc6bd2217 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_85mKr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_85mKr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_85mKr_in_air", + "id": "radioactivity_concentration_of_85mKr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_85mKr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"85mKr\" is the metastable state of the isotope \"krypton-85\" with a half-life of 1.83e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_86Rb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_86Rb_in_air.json index 72df71618..b89de7396 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_86Rb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_86Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_86Rb_in_air", + "id": "radioactivity_concentration_of_86Rb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_86Rb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"86Rb\" is the isotope \"rubidium-86\" with a half-life of 1.87e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_86mRb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_86mRb_in_air.json index 1d4316f12..904fd32e3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_86mRb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_86mRb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_86mRb_in_air", + "id": "radioactivity_concentration_of_86mRb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_86mRb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"86mRb\" is the metastable state of the isotope \"rubidium-86\" with a half-life of 7.04e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_87Kr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_87Kr_in_air.json index 602969b26..b54d68fc2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_87Kr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_87Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_87Kr_in_air", + "id": "radioactivity_concentration_of_87Kr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_87Kr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"87Kr\" is the isotope \"krypton-87\" with a half-life of 5.28e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_87Rb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_87Rb_in_air.json index d1e6ec624..122a2eec9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_87Rb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_87Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_87Rb_in_air", + "id": "radioactivity_concentration_of_87Rb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_87Rb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"87Rb\" is the isotope \"rubidium-87\" with a half-life of 1.71e+13 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_88Kr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_88Kr_in_air.json index 19696524f..8ed90542a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_88Kr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_88Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_88Kr_in_air", + "id": "radioactivity_concentration_of_88Kr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_88Kr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"88Kr\" is the isotope \"krypton-88\" with a half-life of 1.17e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_88Rb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_88Rb_in_air.json index 325877887..949b2c980 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_88Rb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_88Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_88Rb_in_air", + "id": "radioactivity_concentration_of_88Rb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_88Rb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"88Rb\" is the isotope \"rubidium-88\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_89Kr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_89Kr_in_air.json index 5452c6f95..057581d2d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_89Kr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_89Kr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_89Kr_in_air", + "id": "radioactivity_concentration_of_89Kr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_89Kr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Kr\" means the element \"krypton\" and \"89Kr\" is the isotope \"krypton-89\" with a half-life of 2.20e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_89Rb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_89Rb_in_air.json index 993a22185..b31d5a162 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_89Rb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_89Rb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_89Rb_in_air", + "id": "radioactivity_concentration_of_89Rb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_89Rb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Rb\" means the element \"rubidium\" and \"89Rb\" is the isotope \"rubidium-89\" with a half-life of 1.06e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_89Sr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_89Sr_in_air.json index 7b035e277..07dc0c690 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_89Sr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_89Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_89Sr_in_air", + "id": "radioactivity_concentration_of_89Sr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_89Sr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"89Sr\" is the isotope \"strontium-89\" with a half-life of 5.21e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_90Sr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_90Sr_in_air.json index da7d73a17..382725eb0 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_90Sr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_90Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_90Sr_in_air", + "id": "radioactivity_concentration_of_90Sr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_90Sr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"90Sr\" is the isotope \"strontium-90\" with a half-life of 1.02e+04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_90Y_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_90Y_in_air.json index c01f52066..f51198f66 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_90Y_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_90Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_90Y_in_air", + "id": "radioactivity_concentration_of_90Y_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_90Y_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"90Y\" is the isotope \"yttrium-90\" with a half-life of 2.67e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_90mY_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_90mY_in_air.json index f58424180..fd359e14b 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_90mY_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_90mY_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_90mY_in_air", + "id": "radioactivity_concentration_of_90mY_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_90mY_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"90mY\" is the metastable state of the isotope \"yttrium-90\" with a half-life of 1.33e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_91Sr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_91Sr_in_air.json index 8abc61c49..8742016a8 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_91Sr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_91Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_91Sr_in_air", + "id": "radioactivity_concentration_of_91Sr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_91Sr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"91Sr\" is the isotope \"strontium-91\" with a half-life of 3.95e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_91Y_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_91Y_in_air.json index 51f0f682a..cbf6d14ac 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_91Y_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_91Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_91Y_in_air", + "id": "radioactivity_concentration_of_91Y_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_91Y_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"91Y\" is the isotope \"yttrium-91\" with a half-life of 5.86e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_91mY_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_91mY_in_air.json index 97142392c..4a07259d2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_91mY_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_91mY_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_91mY_in_air", + "id": "radioactivity_concentration_of_91mY_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_91mY_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"91mY\" is the metastable state of the isotope \"yttrium-91\" with a half-life of 3.46e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_92Sr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_92Sr_in_air.json index 8954b04d0..60fe13431 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_92Sr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_92Sr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_92Sr_in_air", + "id": "radioactivity_concentration_of_92Sr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_92Sr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Sr\" means the element \"strontium\" and \"92Sr\" is the isotope \"strontium-92\" with a half-life of 1.13e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_92Y_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_92Y_in_air.json index 91f5d7fea..d80dfb2f9 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_92Y_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_92Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_92Y_in_air", + "id": "radioactivity_concentration_of_92Y_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_92Y_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"92Y\" is the isotope \"yttrium-92\" with a half-life of 1.47e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_93Y_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_93Y_in_air.json index 75cabc844..1f3090b58 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_93Y_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_93Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_93Y_in_air", + "id": "radioactivity_concentration_of_93Y_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_93Y_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"93Y\" is the isotope \"yttrium-93\" with a half-life of 4.24e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_93Zr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_93Zr_in_air.json index aaaaf7172..18c1d3ad3 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_93Zr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_93Zr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_93Zr_in_air", + "id": "radioactivity_concentration_of_93Zr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_93Zr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zr\" means the element \"zirconium\" and \"93Zr\" is the isotope \"zirconium-93\" with a half-life of 3.47e+08 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_94Nb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_94Nb_in_air.json index 2601f6073..92d5737fe 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_94Nb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_94Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_94Nb_in_air", + "id": "radioactivity_concentration_of_94Nb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_94Nb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"94Nb\" is the isotope \"niobium-94\" with a half-life of 7.29e+06 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_94Y_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_94Y_in_air.json index eaa232ef4..3f05d48f8 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_94Y_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_94Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_94Y_in_air", + "id": "radioactivity_concentration_of_94Y_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_94Y_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"94Y\" is the isotope \"yttrium-94\" with a half-life of 1.32e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_94mNb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_94mNb_in_air.json index b06fee089..b93178d78 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_94mNb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_94mNb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_94mNb_in_air", + "id": "radioactivity_concentration_of_94mNb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_94mNb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"94mNb\" is the metastable state of the isotope \"niobium-94\" with a half-life of 4.34e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_95Nb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_95Nb_in_air.json index 844989d06..e27dfc759 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_95Nb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_95Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_95Nb_in_air", + "id": "radioactivity_concentration_of_95Nb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_95Nb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"95Nb\" is the isotope \"niobium-95\" with a half-life of 3.52e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_95Y_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_95Y_in_air.json index 9f40d6af3..057eef7ca 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_95Y_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_95Y_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_95Y_in_air", + "id": "radioactivity_concentration_of_95Y_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_95Y_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Y\" means the element \"yttrium\" and \"95Y\" is the isotope \"yttrium-95\" with a half-life of 7.29e-03 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_95Zr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_95Zr_in_air.json index 8e43ad4f4..13642eb8a 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_95Zr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_95Zr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_95Zr_in_air", + "id": "radioactivity_concentration_of_95Zr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_95Zr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zr\" means the element \"zirconium\" and \"95Zr\" is the isotope \"zirconium-95\" with a half-life of 6.52e+01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_95mNb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_95mNb_in_air.json index 54a96908d..19589a42e 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_95mNb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_95mNb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_95mNb_in_air", + "id": "radioactivity_concentration_of_95mNb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_95mNb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"95mNb\" is the metastable state of the isotope \"niobium-95\" with a half-life of 3.61e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_96Nb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_96Nb_in_air.json index fc6838acc..01c69a00d 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_96Nb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_96Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_96Nb_in_air", + "id": "radioactivity_concentration_of_96Nb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_96Nb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"96Nb\" is the isotope \"niobium-96\" with a half-life of 9.75e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_97Nb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_97Nb_in_air.json index e12bcaca5..f3c5360c2 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_97Nb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_97Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_97Nb_in_air", + "id": "radioactivity_concentration_of_97Nb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_97Nb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"97Nb\" is the isotope \"niobium-97\" with a half-life of 5.11e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_97Zr_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_97Zr_in_air.json index fedb1670b..1e6740665 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_97Zr_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_97Zr_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_97Zr_in_air", + "id": "radioactivity_concentration_of_97Zr_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_97Zr_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Zr\" means the element \"zirconium\" and \"97Zr\" is the isotope \"zirconium-97\" with a half-life of 6.98e-01 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_97mNb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_97mNb_in_air.json index 566ad80a1..b885c9fd5 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_97mNb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_97mNb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_97mNb_in_air", + "id": "radioactivity_concentration_of_97mNb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_97mNb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"97mNb\" is the metastable state of the isotope \"niobium-97\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_98Nb_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_98Nb_in_air.json index b6245ce1e..bc7339414 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_98Nb_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_98Nb_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_98Nb_in_air", + "id": "radioactivity_concentration_of_98Nb_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_98Nb_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Nb\" means the element \"niobium\" and \"98Nb\" is the isotope \"niobium-98\" with a half-life of 3.53e-02 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_99Mo_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_99Mo_in_air.json index e98b14c20..a40adbc29 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_99Mo_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_99Mo_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_99Mo_in_air", + "id": "radioactivity_concentration_of_99Mo_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_99Mo_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Mo\" means the element \"molybdenum\" and \"99Mo\" is the isotope \"molybdenum-99\" with a half-life of 2.78e+00 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_99Tc_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_99Tc_in_air.json index 50da6ccc9..ba8ad3fad 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_99Tc_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_99Tc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_99Tc_in_air", + "id": "radioactivity_concentration_of_99Tc_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_99Tc_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"99Tc\" is the isotope \"technetium-99\" with a half-life of 7.79e+07 days.", diff --git a/data_descriptors/standard_name/radioactivity_concentration_of_99mTc_in_air.json b/data_descriptors/standard_name/radioactivity_concentration_of_99mTc_in_air.json index 47d094c3d..fe4e9f88c 100644 --- a/data_descriptors/standard_name/radioactivity_concentration_of_99mTc_in_air.json +++ b/data_descriptors/standard_name/radioactivity_concentration_of_99mTc_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radioactivity_concentration_of_99mTc_in_air", + "id": "radioactivity_concentration_of_99mTc_in_air", "type": "standard_name", "name": "radioactivity_concentration_of_99mTc_in_air", "description": "\"Radioactivity\" means the number of radioactive decays of a material per second. \"Radioactivity concentration\" means radioactivity per unit volume of the medium. \"Tc\" means the element \"technetium\" and \"99mTc\" is the metastable state of the isotope \"technetium-99\" with a half-life of 2.51e-01 days.", diff --git a/data_descriptors/standard_name/radius_of_tropical_cyclone_central_dense_overcast_region.json b/data_descriptors/standard_name/radius_of_tropical_cyclone_central_dense_overcast_region.json index 7a63f0f42..2ce1e1df2 100644 --- a/data_descriptors/standard_name/radius_of_tropical_cyclone_central_dense_overcast_region.json +++ b/data_descriptors/standard_name/radius_of_tropical_cyclone_central_dense_overcast_region.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radius_of_tropical_cyclone_central_dense_overcast_region", + "id": "radius_of_tropical_cyclone_central_dense_overcast_region", "type": "standard_name", "name": "radius_of_tropical_cyclone_central_dense_overcast_region", "description": "The average radius of a central region of clouds in tropical cyclones lacking well-defined eye features, which is computed by averaging the great circle distance in four cardinal directions. The radius in each direction is measured from the estimated storm center position to a warm point that exceeds a threshold brightness temperature at top of atmosphere limit. The threshold applied should be recorded in a coordinate variable having the standard_name of toa_brightness_temperature. A coordinate variable of radiation_wavelength, sensor_band_central_radiation_wavelength, or radiation_frequency may be specified to indicate that the brightness temperature applies at specific wavelengths or frequencies.", diff --git a/data_descriptors/standard_name/radius_of_tropical_cyclone_eye.json b/data_descriptors/standard_name/radius_of_tropical_cyclone_eye.json index cdbf1631d..34a41a34e 100644 --- a/data_descriptors/standard_name/radius_of_tropical_cyclone_eye.json +++ b/data_descriptors/standard_name/radius_of_tropical_cyclone_eye.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radius_of_tropical_cyclone_eye", + "id": "radius_of_tropical_cyclone_eye", "type": "standard_name", "name": "radius_of_tropical_cyclone_eye", "description": "The radius of a tropical cyclone eye is defined to be the great circle distance measured from the cyclone center to the eye wall.", diff --git a/data_descriptors/standard_name/radius_of_tropical_cyclone_maximum_sustained_wind_speed.json b/data_descriptors/standard_name/radius_of_tropical_cyclone_maximum_sustained_wind_speed.json index f5dc14063..e730d6ba0 100644 --- a/data_descriptors/standard_name/radius_of_tropical_cyclone_maximum_sustained_wind_speed.json +++ b/data_descriptors/standard_name/radius_of_tropical_cyclone_maximum_sustained_wind_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/radius_of_tropical_cyclone_maximum_sustained_wind_speed", + "id": "radius_of_tropical_cyclone_maximum_sustained_wind_speed", "type": "standard_name", "name": "radius_of_tropical_cyclone_maximum_sustained_wind_speed", "description": "The great circle distance measured from the tropical cyclone center to the region of sustained 1-minute duration maximum wind speed, as defined by the standard name, tropical_cyclone_maximum_sustained_wind_speed.", diff --git a/data_descriptors/standard_name/rainfall_amount.json b/data_descriptors/standard_name/rainfall_amount.json index 0f9597a8d..b1533062d 100644 --- a/data_descriptors/standard_name/rainfall_amount.json +++ b/data_descriptors/standard_name/rainfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rainfall_amount", + "id": "rainfall_amount", "type": "standard_name", "name": "rainfall_amount", "description": "\"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/rainfall_flux.json b/data_descriptors/standard_name/rainfall_flux.json index 36e01ba49..eaae48be4 100644 --- a/data_descriptors/standard_name/rainfall_flux.json +++ b/data_descriptors/standard_name/rainfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rainfall_flux", + "id": "rainfall_flux", "type": "standard_name", "name": "rainfall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/rainfall_rate.json b/data_descriptors/standard_name/rainfall_rate.json index f30bd9adb..01b7aa31f 100644 --- a/data_descriptors/standard_name/rainfall_rate.json +++ b/data_descriptors/standard_name/rainfall_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rainfall_rate", + "id": "rainfall_rate", "type": "standard_name", "name": "rainfall_rate", "description": null, diff --git a/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json index 993292ffd..a4438b87e 100644 --- a/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", + "id": "rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "rank_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "description": "Rank of the matrix representing the logarithmic scale remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (fractional changes of methane in the retrieved atmosphere relative to the fractional changes of methane in the true atmosphere, Rodgers 2000; Keppens et al., 2015).", diff --git a/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json index b425e1e98..5c4ddefa2 100644 --- a/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", + "id": "rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "rank_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "description": "Rank the matrix representing the remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000).", diff --git a/data_descriptors/standard_name/rate_of_change_test_quality_flag.json b/data_descriptors/standard_name/rate_of_change_test_quality_flag.json index 367c6e39a..957615b4e 100644 --- a/data_descriptors/standard_name/rate_of_change_test_quality_flag.json +++ b/data_descriptors/standard_name/rate_of_change_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rate_of_change_test_quality_flag", + "id": "rate_of_change_test_quality_flag", "type": "standard_name", "name": "rate_of_change_test_quality_flag", "description": "A quality flag that reports the result of the Rate of Change test, which checks that the first order difference of a series of values is within reasonable bounds. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc.json b/data_descriptors/standard_name/rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc.json index 316272b2a..e2de195be 100644 --- a/data_descriptors/standard_name/rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc.json +++ b/data_descriptors/standard_name/rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc", + "id": "rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc", "type": "standard_name", "name": "rate_of_hydroxyl_radical_destruction_due_to_reaction_with_nmvoc", "description": "The \"reaction rate\" is the rate at which the reactants of a chemical reaction form the products. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The rate of \"hydroxyl radical destruction due to reaction with nmvoc\" is the nmvoc reactivity with regard to reactions with OH. It is the weighted sum of the reactivity of all individual nmvoc species with OH. The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species. The abbreviation \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground.json b/data_descriptors/standard_name/ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground.json index c238d5c9d..65248035b 100644 --- a/data_descriptors/standard_name/ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground.json +++ b/data_descriptors/standard_name/ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground", + "id": "ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground", "type": "standard_name", "name": "ratio_of_ice_volume_in_frozen_ground_to_pore_volume_in_unfrozen_ground", "description": "The phrase \"ratio_of_X_to_Y\" means X/Y. \"X_volume\" means the volume occupied by X within the grid cell. Pore volume is the volume of the porosity of the ground under natural, unfrozen conditions. This is often known as \"ice saturation index\".", diff --git a/data_descriptors/standard_name/ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale.json b/data_descriptors/standard_name/ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale.json index ece4216dc..7f942c0a3 100644 --- a/data_descriptors/standard_name/ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale.json +++ b/data_descriptors/standard_name/ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale", + "id": "ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale", "type": "standard_name", "name": "ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale", "description": "The quantity with standard name ratio_of_sea_water_potential_temperature_anomaly_to_relaxation_timescale is a correction term applied to modelled sea water potential temperature. The term is estimated as the deviation of model local sea water potential temperature from an observation-based climatology (e.g. World Ocean Database) weighted by a user-specified relaxation coefficient in s-1 (1/(relaxation timescale)). Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The phrase \"ratio_of_X_to_Y\" means X/Y. The term \"anomaly\" means difference from climatology. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale.json b/data_descriptors/standard_name/ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale.json index 749987253..6c639de95 100644 --- a/data_descriptors/standard_name/ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale.json +++ b/data_descriptors/standard_name/ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale", + "id": "ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale", "type": "standard_name", "name": "ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale", "description": "The quantity with standard name ratio_of_sea_water_practical_salinity_anomaly_to_relaxation_timescale is a correction term applied to modelled sea water practical salinity. The term is estimated as the deviation of model local sea water practical salinity from an observation-based climatology (e.g. World Ocean Database) weighted by a user-specified relaxation coefficient in s-1 (1/(relaxation timescale)). The phrase \"ratio_of_X_to_Y\" means X/Y. The term \"anomaly\" means difference from climatology. Practical Salinity, S_P, is a determination of the salinity of sea water, based on its electrical conductance. The measured conductance, corrected for temperature and pressure, is compared to the conductance of a standard potassium chloride solution, producing a value on the Practical Salinity Scale of 1978 (PSS-78). This name should not be used to describe salinity observations made before 1978, or ones not based on conductance measurements. Conversion of Practical Salinity to other precisely defined salinity measures should use the appropriate formulas specified by TEOS-10. Other standard names for precisely defined salinity quantities are sea_water_absolute_salinity (S_A); sea_water_preformed_salinity (S_*), sea_water_reference_salinity (S_R); sea_water_cox_salinity (S_C), used for salinity observations between 1967 and 1977; and sea_water_knudsen_salinity (S_K), used for salinity observations between 1901 and 1966. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity. Reference: www.teos-10.org; Lewis, 1980 doi:10.1109/JOE.1980.1145448.", diff --git a/data_descriptors/standard_name/ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json index f6584dbba..65b432a04 100644 --- a/data_descriptors/standard_name/ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles", + "id": "ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "ratio_of_volume_extinction_coefficient_to_volume_backwards_scattering_coefficient_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles", "description": "The ratio of volume extinction coefficient to volume backwards scattering coefficient by ranging instrument in air due to ambient aerosol particles (often called \"lidar ratio\") is the ratio of the \"volume extinction coefficient\" and the \"volume backwards scattering coefficient of radiative flux by ranging instrument in air due to ambient aerosol particles\". The ratio is assumed to be related to the same wavelength of incident radiation. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json b/data_descriptors/standard_name/ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json index d3f2f0fff..ce4a06643 100644 --- a/data_descriptors/standard_name/ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json +++ b/data_descriptors/standard_name/ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density", + "id": "ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density", "type": "standard_name", "name": "ratio_of_x_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density", "description": "Sea surface density is the density of sea water near the surface (including the part under sea-ice, if any). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, whether or not they are true longitude and latitude. \"ratio_of_X_to_Y\" means X/Y. \"Ocean rigid lid pressure\" means the pressure at the surface of an ocean model assuming that it is bounded above by a rigid lid.", diff --git a/data_descriptors/standard_name/ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json b/data_descriptors/standard_name/ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json index c6bf88a30..7dbc33777 100644 --- a/data_descriptors/standard_name/ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json +++ b/data_descriptors/standard_name/ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density", + "id": "ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density", "type": "standard_name", "name": "ratio_of_y_derivative_of_ocean_rigid_lid_pressure_to_sea_surface_density", "description": "Sea surface density is the density of sea water near the surface (including the part under sea-ice, if any). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, whether or not they are true longitude and latitude. \"ratio_of_X_to_Y\" means X/Y. \"Ocean rigid lid pressure\" means the pressure at the surface of an ocean model assuming that it is bounded above by a rigid lid.", diff --git a/data_descriptors/standard_name/realization.json b/data_descriptors/standard_name/realization.json index 0d454a33b..3f5f7a0e7 100644 --- a/data_descriptors/standard_name/realization.json +++ b/data_descriptors/standard_name/realization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/realization", + "id": "realization", "type": "standard_name", "name": "realization", "description": "Realization is used to label a dimension that can be thought of as a statistical sample, e.g., labelling members of a model ensemble.", diff --git a/data_descriptors/standard_name/received_power_of_radio_wave_in_air_scattered_by_air.json b/data_descriptors/standard_name/received_power_of_radio_wave_in_air_scattered_by_air.json index 35511afa8..94c2bc6b7 100644 --- a/data_descriptors/standard_name/received_power_of_radio_wave_in_air_scattered_by_air.json +++ b/data_descriptors/standard_name/received_power_of_radio_wave_in_air_scattered_by_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/received_power_of_radio_wave_in_air_scattered_by_air", + "id": "received_power_of_radio_wave_in_air_scattered_by_air", "type": "standard_name", "name": "received_power_of_radio_wave_in_air_scattered_by_air", "description": "Power of a radio wave, that was transmitted by an instrument and propagates in the air where it's scattered by the air due to which its properties change, and it is received again by an instrument. The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities in the air). A standard name referring to the received power of the signal at the instrument.", diff --git a/data_descriptors/standard_name/received_power_of_radio_wave_scattered_by_air.json b/data_descriptors/standard_name/received_power_of_radio_wave_scattered_by_air.json index 25efa4e55..d8783a0e1 100644 --- a/data_descriptors/standard_name/received_power_of_radio_wave_scattered_by_air.json +++ b/data_descriptors/standard_name/received_power_of_radio_wave_scattered_by_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/received_power_of_radio_wave_scattered_by_air", + "id": "received_power_of_radio_wave_scattered_by_air", "type": "standard_name", "name": "received_power_of_radio_wave_scattered_by_air", "description": "The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities), of whatever kind the instrument detects. A standard name referring to the recieved power of the signal at the instrument.", diff --git a/data_descriptors/standard_name/reference_air_pressure_for_atmosphere_vertical_coordinate.json b/data_descriptors/standard_name/reference_air_pressure_for_atmosphere_vertical_coordinate.json index 22f582e44..6f00d9ea0 100644 --- a/data_descriptors/standard_name/reference_air_pressure_for_atmosphere_vertical_coordinate.json +++ b/data_descriptors/standard_name/reference_air_pressure_for_atmosphere_vertical_coordinate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/reference_air_pressure_for_atmosphere_vertical_coordinate", + "id": "reference_air_pressure_for_atmosphere_vertical_coordinate", "type": "standard_name", "name": "reference_air_pressure_for_atmosphere_vertical_coordinate", "description": "For models using a dimensionless vertical coordinate, for example, sigma, hybrid sigma-pressure or eta, the values of the vertical coordinate at the model levels are calculated relative to a reference level. \"Reference air pressure\" is the air pressure at the model reference level. It is a model-dependent constant.", diff --git a/data_descriptors/standard_name/reference_epoch.json b/data_descriptors/standard_name/reference_epoch.json index fb417878f..a32840dad 100644 --- a/data_descriptors/standard_name/reference_epoch.json +++ b/data_descriptors/standard_name/reference_epoch.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/reference_epoch", + "id": "reference_epoch", "type": "standard_name", "name": "reference_epoch", "description": "The period of time over which a parameter has been summarised (usually by averaging) in order to provide a reference (baseline) against which data has been compared. When a coordinate, scalar coordinate, or auxiliary coordinate variable with this standard name has bounds, then the bounds specify the beginning and end of the time period over which the reference was determined. If the reference represents an instant in time, rather than a period, then bounds may be omitted. It is not the time for which the actual measurements are valid; the standard name of time should be used for that.", diff --git a/data_descriptors/standard_name/reference_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/reference_mole_fraction_of_methane_in_air.json index 1ff56b7aa..34242222c 100644 --- a/data_descriptors/standard_name/reference_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/reference_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/reference_mole_fraction_of_methane_in_air", + "id": "reference_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "reference_mole_fraction_of_methane_in_air", "description": "This methane field acts as a reference methane field in a diagnostic call to the radiation scheme. \"Mole fraction\" is used in the construction \"mole_fraction_of_X_in_Y\", where X is a material constituent of Y. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/reference_mole_fraction_of_ozone_in_air.json index 52e919d67..3b0a6a561 100644 --- a/data_descriptors/standard_name/reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/reference_mole_fraction_of_ozone_in_air", + "id": "reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "reference_mole_fraction_of_ozone_in_air", "description": "This ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", diff --git a/data_descriptors/standard_name/reference_pressure.json b/data_descriptors/standard_name/reference_pressure.json index eb339d09c..6c4c196f3 100644 --- a/data_descriptors/standard_name/reference_pressure.json +++ b/data_descriptors/standard_name/reference_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/reference_pressure", + "id": "reference_pressure", "type": "standard_name", "name": "reference_pressure", "description": "A constant pressure value, typically representative of mean sea level pressure, which can be used in defining coordinates or functions of state.", diff --git a/data_descriptors/standard_name/reference_sea_water_density_for_boussinesq_approximation.json b/data_descriptors/standard_name/reference_sea_water_density_for_boussinesq_approximation.json index b7f366caa..235f8d609 100644 --- a/data_descriptors/standard_name/reference_sea_water_density_for_boussinesq_approximation.json +++ b/data_descriptors/standard_name/reference_sea_water_density_for_boussinesq_approximation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/reference_sea_water_density_for_boussinesq_approximation", + "id": "reference_sea_water_density_for_boussinesq_approximation", "type": "standard_name", "name": "reference_sea_water_density_for_boussinesq_approximation", "description": "Sea water density is the in-situ density (not the potential density). For a rigid lid Boussinesq geopotential ocean model the density of the sea water is maintained at a constant reference density. In a model using the rigid lid Boussinesq approximation , the vertical grid coordinates (and hence the grid cell volumes) are time invariant.", diff --git a/data_descriptors/standard_name/region.json b/data_descriptors/standard_name/region.json index 631ba1dc5..4dc78aded 100644 --- a/data_descriptors/standard_name/region.json +++ b/data_descriptors/standard_name/region.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/region", + "id": "region", "type": "standard_name", "name": "region", "description": "A variable with the standard name of region contains either strings which indicate a geographical region or flags which can be translated to strings using flag_values and flag_meanings attributes. These strings are standardised. Values must be taken from the CF standard region list.", diff --git a/data_descriptors/standard_name/relative_humidity.json b/data_descriptors/standard_name/relative_humidity.json index 55145a0a2..b769944e8 100644 --- a/data_descriptors/standard_name/relative_humidity.json +++ b/data_descriptors/standard_name/relative_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/relative_humidity", + "id": "relative_humidity", "type": "standard_name", "name": "relative_humidity", "description": null, diff --git a/data_descriptors/standard_name/relative_humidity_for_aerosol_particle_size_selection.json b/data_descriptors/standard_name/relative_humidity_for_aerosol_particle_size_selection.json index 491cf19af..24f8ea7ab 100644 --- a/data_descriptors/standard_name/relative_humidity_for_aerosol_particle_size_selection.json +++ b/data_descriptors/standard_name/relative_humidity_for_aerosol_particle_size_selection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/relative_humidity_for_aerosol_particle_size_selection", + "id": "relative_humidity_for_aerosol_particle_size_selection", "type": "standard_name", "name": "relative_humidity_for_aerosol_particle_size_selection", "description": "Relative humidity at which the size of a sampled aerosol particle was selected. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself.", diff --git a/data_descriptors/standard_name/relative_platform_azimuth_angle.json b/data_descriptors/standard_name/relative_platform_azimuth_angle.json index 51fa22aee..490584d23 100644 --- a/data_descriptors/standard_name/relative_platform_azimuth_angle.json +++ b/data_descriptors/standard_name/relative_platform_azimuth_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/relative_platform_azimuth_angle", + "id": "relative_platform_azimuth_angle", "type": "standard_name", "name": "relative_platform_azimuth_angle", "description": "The quantity with standard name relative_platform_azimuth_angle is the difference between the viewing geometries from two different platforms over the same observation target. It is the difference between the values of two quantities with standard name platform_azimuth_angle. There is no standardized sign convention for relative_platform_azimuth_angle. \"Observation target\" means a location on the Earth defined by the sensor performing the observations. A standard name also exists for relative_sensor_azimuth_angle. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated azimuth angle. A \"platform\" is a structure or vehicle that serves as a base for mounting sensors. Platforms include, but are not limited to, satellites, aeroplanes, ships, buoys, instruments, ground stations, and masts.", diff --git a/data_descriptors/standard_name/relative_sensor_azimuth_angle.json b/data_descriptors/standard_name/relative_sensor_azimuth_angle.json index 49ba1655f..ce0c8d434 100644 --- a/data_descriptors/standard_name/relative_sensor_azimuth_angle.json +++ b/data_descriptors/standard_name/relative_sensor_azimuth_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/relative_sensor_azimuth_angle", + "id": "relative_sensor_azimuth_angle", "type": "standard_name", "name": "relative_sensor_azimuth_angle", "description": "relative_sensor_azimuth_angle is the difference between the viewing geometries from two different sensors over the same observation target. It is the difference between the values of two quantities with standard name sensor_azimuth_angle. There is no standardized sign convention for relative_sensor_azimuth_angle. \"Observation target\" means a location on the Earth defined by the sensor performing the observations. A standard name also exists for relative_platform_azimuth_angle, where \"platform\" refers to the vehicle from which observations are made e.g. aeroplane, ship, or satellite. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated azimuth angle.", diff --git a/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json index a609c59bc..2e42a691e 100644 --- a/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", + "id": "remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "description": "Logarithmic scale averaging kernels of the methane mole fractions obtained by a remote sensing observation (Rodgers, 2020). These kernels are also called fractional averaging kernels (Keppens et al., 2015) They represent the fractional changes of methane in the retrieved atmosphere relative to the fractional changes of methane in the true atmosphere.", diff --git a/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json index 237f8ac44..1df9da496 100644 --- a/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", + "id": "remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "description": "Averaging kernels of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000).", diff --git a/data_descriptors/standard_name/richardson_number_in_sea_water.json b/data_descriptors/standard_name/richardson_number_in_sea_water.json index f44687b42..7751f7fbc 100644 --- a/data_descriptors/standard_name/richardson_number_in_sea_water.json +++ b/data_descriptors/standard_name/richardson_number_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/richardson_number_in_sea_water", + "id": "richardson_number_in_sea_water", "type": "standard_name", "name": "richardson_number_in_sea_water", "description": "Richardson number is a measure of dynamic stability and can be used to diagnose the existence of turbulent flow. It is defined as the ratio of the buoyant suppression of turbulence (i.e. how statically stable or unstable the conditions are) to the kinetic energy available to generate turbulence in a shear flow.", diff --git a/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json index 89762c593..f185fae35 100644 --- a/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", + "id": "right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "right_singular_vector_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "description": "Right singular vectors of the matrix representing the logarithmic scale remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000; Keppens et al., 2015).", diff --git a/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json index e3546b84c..c6ea60d08 100644 --- a/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", + "id": "right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "right_singular_vector_of_remote_sensing_averaging_kernel_of_mole_fraction_of_methane_in_air", "description": "Right singular vectors of the matrix representing the remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000).", diff --git a/data_descriptors/standard_name/root_depth.json b/data_descriptors/standard_name/root_depth.json index 6729cb2ba..d098e1925 100644 --- a/data_descriptors/standard_name/root_depth.json +++ b/data_descriptors/standard_name/root_depth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/root_depth", + "id": "root_depth", "type": "standard_name", "name": "root_depth", "description": "Depth is the vertical distance below the surface. The root depth is maximum depth of soil reached by plant roots, from which they can extract moisture.", diff --git a/data_descriptors/standard_name/root_mass_content_of_carbon.json b/data_descriptors/standard_name/root_mass_content_of_carbon.json index 296b2b765..23742e770 100644 --- a/data_descriptors/standard_name/root_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/root_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/root_mass_content_of_carbon", + "id": "root_mass_content_of_carbon", "type": "standard_name", "name": "root_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area.", diff --git a/data_descriptors/standard_name/root_mass_content_of_nitrogen.json b/data_descriptors/standard_name/root_mass_content_of_nitrogen.json index cea120acf..ef6a865a8 100644 --- a/data_descriptors/standard_name/root_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/root_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/root_mass_content_of_nitrogen", + "id": "root_mass_content_of_nitrogen", "type": "standard_name", "name": "root_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area.", diff --git a/data_descriptors/standard_name/runoff_amount.json b/data_descriptors/standard_name/runoff_amount.json index 04bb60f62..b089923bc 100644 --- a/data_descriptors/standard_name/runoff_amount.json +++ b/data_descriptors/standard_name/runoff_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/runoff_amount", + "id": "runoff_amount", "type": "standard_name", "name": "runoff_amount", "description": "\"Amount\" means mass per unit area. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/runoff_amount_excluding_baseflow.json b/data_descriptors/standard_name/runoff_amount_excluding_baseflow.json index 6446c7743..3c4274d06 100644 --- a/data_descriptors/standard_name/runoff_amount_excluding_baseflow.json +++ b/data_descriptors/standard_name/runoff_amount_excluding_baseflow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/runoff_amount_excluding_baseflow", + "id": "runoff_amount_excluding_baseflow", "type": "standard_name", "name": "runoff_amount_excluding_baseflow", "description": "Runoff is the liquid water which drains from land. \"Runoff_excluding_baseflow\" is the sum of surface runoff and subsurface runoff excluding baseflow. Baseflow is subsurface runoff which takes place below the level of the water table. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/runoff_flux.json b/data_descriptors/standard_name/runoff_flux.json index 8be1c80c3..cd722d5ac 100644 --- a/data_descriptors/standard_name/runoff_flux.json +++ b/data_descriptors/standard_name/runoff_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/runoff_flux", + "id": "runoff_flux", "type": "standard_name", "name": "runoff_flux", "description": "Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json index 496515909..1bdac191f 100644 --- a/data_descriptors/standard_name/salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", + "id": "salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of ice mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion. The quantity with standard name salt_flux_into_sea_water_due_to_sea_ice_thermodynamics is negative during ice growth when salt becomes embedded into the ice and positive during ice melting when salt is released into the ocean. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/salt_flux_into_sea_water_from_rivers.json b/data_descriptors/standard_name/salt_flux_into_sea_water_from_rivers.json index e1e3c53fc..02ae99a5c 100644 --- a/data_descriptors/standard_name/salt_flux_into_sea_water_from_rivers.json +++ b/data_descriptors/standard_name/salt_flux_into_sea_water_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/salt_flux_into_sea_water_from_rivers", + "id": "salt_flux_into_sea_water_from_rivers", "type": "standard_name", "name": "salt_flux_into_sea_water_from_rivers", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/scattering_angle.json b/data_descriptors/standard_name/scattering_angle.json index f3328d4cd..df729870f 100644 --- a/data_descriptors/standard_name/scattering_angle.json +++ b/data_descriptors/standard_name/scattering_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/scattering_angle", + "id": "scattering_angle", "type": "standard_name", "name": "scattering_angle", "description": "The scattering angle is that between the direction of the beam of incident radiation and the direction into which it is scattered.", diff --git a/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_cloud_region.json b/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_cloud_region.json index 7a7bcc761..952b7ba5f 100644 --- a/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_cloud_region.json +++ b/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_cloud_region.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/scene_type_of_dvorak_tropical_cyclone_cloud_region", + "id": "scene_type_of_dvorak_tropical_cyclone_cloud_region", "type": "standard_name", "name": "scene_type_of_dvorak_tropical_cyclone_cloud_region", "description": "A variable with the standard name of scene_type_of_dvorak_tropical_cyclone_cloud_region contains integers which can be translated to strings using flag_values and flag_meanings attributes. It indicates the Advanced Dvorak Technique tropical cyclone cloud region scene type chosen from the following list: uniform_central_dense_overcast; embedded_center; irregular_central_dense_overcast; curved_band; shear. Alternatively, the data variable may contain strings chosen from the same standardised list to indicate the scene type. Reference: Olander, T. L., & Velden, C. S., The Advanced Dvorak Technique: Continued Development of an Objective Scheme to Estimate Tropical Cyclone Intensity Using Geostationary Infrared Satellite Imagery (2007). American Meteorological Society Weather and Forecasting, 22, 287-298.", diff --git a/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_eye_region.json b/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_eye_region.json index 2421f3170..cf3271474 100644 --- a/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_eye_region.json +++ b/data_descriptors/standard_name/scene_type_of_dvorak_tropical_cyclone_eye_region.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/scene_type_of_dvorak_tropical_cyclone_eye_region", + "id": "scene_type_of_dvorak_tropical_cyclone_eye_region", "type": "standard_name", "name": "scene_type_of_dvorak_tropical_cyclone_eye_region", "description": "A variable with the standard name of scene_type_of_dvorak_tropical_cyclone_eye_region contains integers which can be translated to strings using flag_values and flag_meanings attributes. It indicates the Advanced Dvorak Technique tropical cyclone eye region scene type chosen from the following list: clear_ragged_or_obscured_eye; pinhole_eye; large_eye; no_eye. Alternatively, the data variable may contain strings chosen from the same standardised list to indicate the scene type. Reference: Olander, T. L., & Velden, C. S., The Advanced Dvorak Technique: Continued Development of an Objective Scheme to Estimate Tropical Cyclone Intensity Using Geostationary Infrared Satellite Imagery (2007). American Meteorological Society Weather and Forecasting, 22, 287-298.", diff --git a/data_descriptors/standard_name/sea_area.json b/data_descriptors/standard_name/sea_area.json index 33ee19f3f..fca58ad12 100644 --- a/data_descriptors/standard_name/sea_area.json +++ b/data_descriptors/standard_name/sea_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_area", + "id": "sea_area", "type": "standard_name", "name": "sea_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\".", diff --git a/data_descriptors/standard_name/sea_area_fraction.json b/data_descriptors/standard_name/sea_area_fraction.json index 632f0636b..746f0a8e6 100644 --- a/data_descriptors/standard_name/sea_area_fraction.json +++ b/data_descriptors/standard_name/sea_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_area_fraction", + "id": "sea_area_fraction", "type": "standard_name", "name": "sea_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/sea_binary_mask.json b/data_descriptors/standard_name/sea_binary_mask.json index f08217bf6..014a10c97 100644 --- a/data_descriptors/standard_name/sea_binary_mask.json +++ b/data_descriptors/standard_name/sea_binary_mask.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_binary_mask", + "id": "sea_binary_mask", "type": "standard_name", "name": "sea_binary_mask", "description": "X\"_binary_mask\" has 1 where condition X is met, 0 elsewhere. 1 = sea, 0 = land.", diff --git a/data_descriptors/standard_name/sea_floor_depth_below_geoid.json b/data_descriptors/standard_name/sea_floor_depth_below_geoid.json index a39143952..3162d7b95 100644 --- a/data_descriptors/standard_name/sea_floor_depth_below_geoid.json +++ b/data_descriptors/standard_name/sea_floor_depth_below_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_depth_below_geoid", + "id": "sea_floor_depth_below_geoid", "type": "standard_name", "name": "sea_floor_depth_below_geoid", "description": "\"Depth_below_X\" means the vertical distance below the named surface X. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/sea_floor_depth_below_geopotential_datum.json b/data_descriptors/standard_name/sea_floor_depth_below_geopotential_datum.json index b6c341d64..c88c493f3 100644 --- a/data_descriptors/standard_name/sea_floor_depth_below_geopotential_datum.json +++ b/data_descriptors/standard_name/sea_floor_depth_below_geopotential_datum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_depth_below_geopotential_datum", + "id": "sea_floor_depth_below_geopotential_datum", "type": "standard_name", "name": "sea_floor_depth_below_geopotential_datum", "description": "\"Depth_below_X\" means the vertical distance below the named surface X. The \"geopotential datum\" is any estimated surface of constant geopotential used as a datum i.e. a reference level; for the geoid as a datum, specific standard names are available. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/sea_floor_depth_below_mean_sea_level.json b/data_descriptors/standard_name/sea_floor_depth_below_mean_sea_level.json index 6c548e3e4..3007c5c1c 100644 --- a/data_descriptors/standard_name/sea_floor_depth_below_mean_sea_level.json +++ b/data_descriptors/standard_name/sea_floor_depth_below_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_depth_below_mean_sea_level", + "id": "sea_floor_depth_below_mean_sea_level", "type": "standard_name", "name": "sea_floor_depth_below_mean_sea_level", "description": "\"Depth_below_X\" means the vertical distance below the named surface X. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals.", diff --git a/data_descriptors/standard_name/sea_floor_depth_below_reference_ellipsoid.json b/data_descriptors/standard_name/sea_floor_depth_below_reference_ellipsoid.json index d96e73e1e..56d7ffaf2 100644 --- a/data_descriptors/standard_name/sea_floor_depth_below_reference_ellipsoid.json +++ b/data_descriptors/standard_name/sea_floor_depth_below_reference_ellipsoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_depth_below_reference_ellipsoid", + "id": "sea_floor_depth_below_reference_ellipsoid", "type": "standard_name", "name": "sea_floor_depth_below_reference_ellipsoid", "description": "\"Depth_below_X\" means the vertical distance below the named surface X. A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/sea_floor_depth_below_sea_surface.json b/data_descriptors/standard_name/sea_floor_depth_below_sea_surface.json index 9c5b25161..dec7c505c 100644 --- a/data_descriptors/standard_name/sea_floor_depth_below_sea_surface.json +++ b/data_descriptors/standard_name/sea_floor_depth_below_sea_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_depth_below_sea_surface", + "id": "sea_floor_depth_below_sea_surface", "type": "standard_name", "name": "sea_floor_depth_below_sea_surface", "description": "The sea_floor_depth_below_sea_surface is the vertical distance between the sea surface and the seabed as measured at a given point in space including the variance caused by tides and possibly waves.", diff --git a/data_descriptors/standard_name/sea_floor_sediment_age_before_1950.json b/data_descriptors/standard_name/sea_floor_sediment_age_before_1950.json index 47c5fb086..0b62d4d7f 100644 --- a/data_descriptors/standard_name/sea_floor_sediment_age_before_1950.json +++ b/data_descriptors/standard_name/sea_floor_sediment_age_before_1950.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_sediment_age_before_1950", + "id": "sea_floor_sediment_age_before_1950", "type": "standard_name", "name": "sea_floor_sediment_age_before_1950", "description": "\"Sea floor sediment\" is sediment deposited at the sea bed. \"Sediment age\" means the length of time elapsed since the sediment was deposited. The phrase \"before_1950\" is a transparent representation of the phrase \"before_present\", often used in the geological and archaeological domains to refer to time elapsed between an event and 1950 AD.", diff --git a/data_descriptors/standard_name/sea_floor_sediment_grain_size.json b/data_descriptors/standard_name/sea_floor_sediment_grain_size.json index be987f6db..3084de555 100644 --- a/data_descriptors/standard_name/sea_floor_sediment_grain_size.json +++ b/data_descriptors/standard_name/sea_floor_sediment_grain_size.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_floor_sediment_grain_size", + "id": "sea_floor_sediment_grain_size", "type": "standard_name", "name": "sea_floor_sediment_grain_size", "description": "The average size of grains (also known as particles) in a sediment sample.", diff --git a/data_descriptors/standard_name/sea_ice_albedo.json b/data_descriptors/standard_name/sea_ice_albedo.json index 939b3103d..9edef1073 100644 --- a/data_descriptors/standard_name/sea_ice_albedo.json +++ b/data_descriptors/standard_name/sea_ice_albedo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_albedo", + "id": "sea_ice_albedo", "type": "standard_name", "name": "sea_ice_albedo", "description": "The albedo of sea ice. Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_amount.json b/data_descriptors/standard_name/sea_ice_amount.json index b9db39aef..253a6af3c 100644 --- a/data_descriptors/standard_name/sea_ice_amount.json +++ b/data_descriptors/standard_name/sea_ice_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_amount", + "id": "sea_ice_amount", "type": "standard_name", "name": "sea_ice_amount", "description": "\"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_and_surface_snow_amount.json b/data_descriptors/standard_name/sea_ice_and_surface_snow_amount.json index dd6d23523..019eafa8c 100644 --- a/data_descriptors/standard_name/sea_ice_and_surface_snow_amount.json +++ b/data_descriptors/standard_name/sea_ice_and_surface_snow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_and_surface_snow_amount", + "id": "sea_ice_and_surface_snow_amount", "type": "standard_name", "name": "sea_ice_and_surface_snow_amount", "description": "\"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_area.json b/data_descriptors/standard_name/sea_ice_area.json index 34f828f65..01d9d0112 100644 --- a/data_descriptors/standard_name/sea_ice_area.json +++ b/data_descriptors/standard_name/sea_ice_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_area", + "id": "sea_ice_area", "type": "standard_name", "name": "sea_ice_area", "description": "\"X_area\" means the horizontal area occupied by X within the grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\". \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_area_fraction.json b/data_descriptors/standard_name/sea_ice_area_fraction.json index a289dd898..0f0177a02 100644 --- a/data_descriptors/standard_name/sea_ice_area_fraction.json +++ b/data_descriptors/standard_name/sea_ice_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_area_fraction", + "id": "sea_ice_area_fraction", "type": "standard_name", "name": "sea_ice_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called \"sea ice concentration\". \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_area_transport_across_line.json b/data_descriptors/standard_name/sea_ice_area_transport_across_line.json index 616a7fbb9..df110f811 100644 --- a/data_descriptors/standard_name/sea_ice_area_transport_across_line.json +++ b/data_descriptors/standard_name/sea_ice_area_transport_across_line.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_area_transport_across_line", + "id": "sea_ice_area_transport_across_line", "type": "standard_name", "name": "sea_ice_area_transport_across_line", "description": "Transport \"across_line\" means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_average_normal_horizontal_stress.json b/data_descriptors/standard_name/sea_ice_average_normal_horizontal_stress.json index eec7e1572..57884c6f3 100644 --- a/data_descriptors/standard_name/sea_ice_average_normal_horizontal_stress.json +++ b/data_descriptors/standard_name/sea_ice_average_normal_horizontal_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_average_normal_horizontal_stress", + "id": "sea_ice_average_normal_horizontal_stress", "type": "standard_name", "name": "sea_ice_average_normal_horizontal_stress", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. Axial stress is the symmetric component of the tensor representing the gradient of internal forces (e.g. in ice). Horizontal stress refers to the stress in the horizontal plane. \"Horizontal\" refers to the local horizontal in the location of the sea ice, i.e., perpendicular to the local gravity vector. Average normal stress refers to the average of the diagonal elements of the stress tensor and represents the first invariant of stress.", diff --git a/data_descriptors/standard_name/sea_ice_basal_drag_coefficient_for_momentum_in_sea_water.json b/data_descriptors/standard_name/sea_ice_basal_drag_coefficient_for_momentum_in_sea_water.json index 25b00891b..b333b1fcb 100644 --- a/data_descriptors/standard_name/sea_ice_basal_drag_coefficient_for_momentum_in_sea_water.json +++ b/data_descriptors/standard_name/sea_ice_basal_drag_coefficient_for_momentum_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_basal_drag_coefficient_for_momentum_in_sea_water", + "id": "sea_ice_basal_drag_coefficient_for_momentum_in_sea_water", "type": "standard_name", "name": "sea_ice_basal_drag_coefficient_for_momentum_in_sea_water", "description": "The quantity with standard name sea_ice_basal_drag_coefficient_for_momentum_in_sea_water is used to calculate the oceanic momentum drag on sea ice movement. Basal drag is a resistive stress opposing ice flow at the boundary between sea ice and sea water. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_basal_temperature.json b/data_descriptors/standard_name/sea_ice_basal_temperature.json index 31d25cdc7..3f759ec93 100644 --- a/data_descriptors/standard_name/sea_ice_basal_temperature.json +++ b/data_descriptors/standard_name/sea_ice_basal_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_basal_temperature", + "id": "sea_ice_basal_temperature", "type": "standard_name", "name": "sea_ice_basal_temperature", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The standard name sea_ice_basal_temperature means the temperature of the sea ice at its lower boundary. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_ice_classification.json b/data_descriptors/standard_name/sea_ice_classification.json index a5aca63a8..8a4add342 100644 --- a/data_descriptors/standard_name/sea_ice_classification.json +++ b/data_descriptors/standard_name/sea_ice_classification.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_classification", + "id": "sea_ice_classification", "type": "standard_name", "name": "sea_ice_classification", "description": "A variable with the standard name of sea_ice_classification contains strings which indicate the character of the ice surface e.g. open_ice, or first_year_ice. These strings have not yet been standardised. However, and whenever possible, they should follow the terminology defined in the WMO Standard Nomenclature for Sea Ice Classification. Alternatively, the data variable may contain integers which can be translated to strings using flag_values and flag_meanings attributes. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_draft.json b/data_descriptors/standard_name/sea_ice_draft.json index 5c3bc6207..2e78e90fb 100644 --- a/data_descriptors/standard_name/sea_ice_draft.json +++ b/data_descriptors/standard_name/sea_ice_draft.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_draft", + "id": "sea_ice_draft", "type": "standard_name", "name": "sea_ice_draft", "description": "Sea ice draft is the depth of the sea-ice lower surface below the water surface. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_extent.json b/data_descriptors/standard_name/sea_ice_extent.json index 1c42d7de3..ca91a51dc 100644 --- a/data_descriptors/standard_name/sea_ice_extent.json +++ b/data_descriptors/standard_name/sea_ice_extent.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_extent", + "id": "sea_ice_extent", "type": "standard_name", "name": "sea_ice_extent", "description": "The term sea_ice_extent means the total area of all grid cells in which the sea ice area fraction equals or exceeds a threshold, often chosen to be 15 per cent. The threshold must be specified by supplying a coordinate variable or scalar coordinate variable with the standard name of sea_ice_area_fraction. The horizontal domain over which sea ice extent is calculated is described by the associated coordinate variables and coordinate bounds or by a coordinate variable or scalar coordinate variable with the standard name of \"region\" supplied according to section 6.1.1 of the CF conventions. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_floe_diameter.json b/data_descriptors/standard_name/sea_ice_floe_diameter.json index ec2bb6213..9634d31ef 100644 --- a/data_descriptors/standard_name/sea_ice_floe_diameter.json +++ b/data_descriptors/standard_name/sea_ice_floe_diameter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_floe_diameter", + "id": "sea_ice_floe_diameter", "type": "standard_name", "name": "sea_ice_floe_diameter", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. An ice floe is a flat expanse of sea ice, generally taken to be less than 10 km across. ice_floe_diameter corresponds to the diameter of a circle with the same area as the ice floe.", diff --git a/data_descriptors/standard_name/sea_ice_freeboard.json b/data_descriptors/standard_name/sea_ice_freeboard.json index 1ccd76db6..24fc4c8c9 100644 --- a/data_descriptors/standard_name/sea_ice_freeboard.json +++ b/data_descriptors/standard_name/sea_ice_freeboard.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_freeboard", + "id": "sea_ice_freeboard", "type": "standard_name", "name": "sea_ice_freeboard", "description": "Sea ice freeboard is the height of the sea-ice upper surface above the water surface. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_mass.json b/data_descriptors/standard_name/sea_ice_mass.json index a8926de4f..adf0cfec1 100644 --- a/data_descriptors/standard_name/sea_ice_mass.json +++ b/data_descriptors/standard_name/sea_ice_mass.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_mass", + "id": "sea_ice_mass", "type": "standard_name", "name": "sea_ice_mass", "description": "The horizontal domain over which sea ice mass is calculated is described by the associated coordinate variables and coordinate bounds or by a coordinate variable or scalar coordinate variable with the standard name of \"region\" supplied according to section 6.1.1 of the CF conventions.\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll.json b/data_descriptors/standard_name/sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll.json index df8c12770..a0cef95d3 100644 --- a/data_descriptors/standard_name/sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll.json +++ b/data_descriptors/standard_name/sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll", + "id": "sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll", "type": "standard_name", "name": "sea_ice_mass_content_of_ice_algae_expressed_as_chlorophyll", "description": "Sum of chlorophyll from all ice algal group concentrations. \"Content\" indicates a quantity per unit area. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"sea_ice content\" of a quantity refers to the vertical integral from the surface down to the bottom of the sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. Sea-ice algae (or simply 'ice algae' when the context of sea ice is clear) refer to algae uniquely able to thrive within the sea-ice environment. This distinction from phytoplankton is essential, as several phytoplankton species that become trapped in sea ice eventually perish due to a lack of genetic adaptation or acclimation strategies to survive such conditions. By referring to 'sea-ice algae,' we highlight these algae's specific features and ecological significance within the sea-ice habitat. Chlorophylls are the green pigments found in most plants, algae and cyanobacteria; their presence is essential for photosynthesis to take place. There are several different forms of chlorophyll that occur naturally. All contain a chlorin ring (chemical formula C20H16N4) which gives the green pigment and a side chain whose structure varies. The naturally occurring forms of chlorophyll contain between 35 and 55 carbon atoms.", diff --git a/data_descriptors/standard_name/sea_ice_mass_content_of_salt.json b/data_descriptors/standard_name/sea_ice_mass_content_of_salt.json index 201c50549..b908d5885 100644 --- a/data_descriptors/standard_name/sea_ice_mass_content_of_salt.json +++ b/data_descriptors/standard_name/sea_ice_mass_content_of_salt.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_mass_content_of_salt", + "id": "sea_ice_mass_content_of_salt", "type": "standard_name", "name": "sea_ice_mass_content_of_salt", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. \"Content\" indicates a quantity per unit area. The \"sea_ice content\" of a quantity refers to the vertical integral from the surface down to the bottom of the sea ice.", diff --git a/data_descriptors/standard_name/sea_ice_melt_pond_thickness.json b/data_descriptors/standard_name/sea_ice_melt_pond_thickness.json index 6523f1a0c..1cd79d8de 100644 --- a/data_descriptors/standard_name/sea_ice_melt_pond_thickness.json +++ b/data_descriptors/standard_name/sea_ice_melt_pond_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_melt_pond_thickness", + "id": "sea_ice_melt_pond_thickness", "type": "standard_name", "name": "sea_ice_melt_pond_thickness", "description": "\"Thickness\" means the vertical extent of a layer. Melt ponds occur on top of the existing sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_mole_content_of_ice_algae_expressed_as_carbon.json b/data_descriptors/standard_name/sea_ice_mole_content_of_ice_algae_expressed_as_carbon.json index ea6908d58..0e3e7107c 100644 --- a/data_descriptors/standard_name/sea_ice_mole_content_of_ice_algae_expressed_as_carbon.json +++ b/data_descriptors/standard_name/sea_ice_mole_content_of_ice_algae_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_mole_content_of_ice_algae_expressed_as_carbon", + "id": "sea_ice_mole_content_of_ice_algae_expressed_as_carbon", "type": "standard_name", "name": "sea_ice_mole_content_of_ice_algae_expressed_as_carbon", "description": "Sum of ice algal carbon component content. \"Content\" indicates a quantity per unit area. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"sea_ice content\" of a quantity refers to the vertical integral from the surface down to the bottom of the sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. Sea-ice algae (or simply 'ice algae' when the context of sea ice is clear) refer to algae uniquely able to thrive within the sea-ice environment. This distinction from phytoplankton is essential, as several phytoplankton species that become trapped in sea ice eventually perish due to a lack of genetic adaptation or acclimation strategies to survive such conditions. By referring to 'sea-ice algae,' we highlight these algae's specific features and ecological significance within the sea-ice habitat.", diff --git a/data_descriptors/standard_name/sea_ice_mole_content_of_nitrate.json b/data_descriptors/standard_name/sea_ice_mole_content_of_nitrate.json index f9a5c91d4..14fad154b 100644 --- a/data_descriptors/standard_name/sea_ice_mole_content_of_nitrate.json +++ b/data_descriptors/standard_name/sea_ice_mole_content_of_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_mole_content_of_nitrate", + "id": "sea_ice_mole_content_of_nitrate", "type": "standard_name", "name": "sea_ice_mole_content_of_nitrate", "description": "Mole amount means moles of substance per unit area. \"Content\" indicates a quantity per unit area. The chemical formula for the nitrate anion is NO3-. The \"sea_ice content\" of a quantity refers to the vertical integral from the surface down to the bottom of the sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_mole_content_of_silicon.json b/data_descriptors/standard_name/sea_ice_mole_content_of_silicon.json index 7cdccf630..ae4caeaa9 100644 --- a/data_descriptors/standard_name/sea_ice_mole_content_of_silicon.json +++ b/data_descriptors/standard_name/sea_ice_mole_content_of_silicon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_mole_content_of_silicon", + "id": "sea_ice_mole_content_of_silicon", "type": "standard_name", "name": "sea_ice_mole_content_of_silicon", "description": "Mole amount means moles of substance per unit area. \"Content\" indicates a quantity per unit area. The \"sea_ice content\" of a quantity refers to the vertical integral from the surface down to the bottom of the sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_salinity.json b/data_descriptors/standard_name/sea_ice_salinity.json index 96185de7d..b3c7ae5f2 100644 --- a/data_descriptors/standard_name/sea_ice_salinity.json +++ b/data_descriptors/standard_name/sea_ice_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_salinity", + "id": "sea_ice_salinity", "type": "standard_name", "name": "sea_ice_salinity", "description": "Sea ice salinity is the salt content of sea ice, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_speed.json b/data_descriptors/standard_name/sea_ice_speed.json index 078004308..fc1f034cd 100644 --- a/data_descriptors/standard_name/sea_ice_speed.json +++ b/data_descriptors/standard_name/sea_ice_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_speed", + "id": "sea_ice_speed", "type": "standard_name", "name": "sea_ice_speed", "description": "Speed is the magnitude of velocity. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_surface_temperature.json b/data_descriptors/standard_name/sea_ice_surface_temperature.json index fe8d572ae..42b8d71fa 100644 --- a/data_descriptors/standard_name/sea_ice_surface_temperature.json +++ b/data_descriptors/standard_name/sea_ice_surface_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_surface_temperature", + "id": "sea_ice_surface_temperature", "type": "standard_name", "name": "sea_ice_surface_temperature", "description": "The surface temperature is the (skin) temperature at the interface, not the bulk temperature of the medium above or below. \"Sea ice surface temperature\" is the temperature that exists at the interface of sea ice and an overlying medium which may be air or snow. In areas of snow covered sea ice, sea_ice_surface_temperature is not the same as the quantity with standard name surface_temperature. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_ice_temperature.json b/data_descriptors/standard_name/sea_ice_temperature.json index fe13131f9..938ccd948 100644 --- a/data_descriptors/standard_name/sea_ice_temperature.json +++ b/data_descriptors/standard_name/sea_ice_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_temperature", + "id": "sea_ice_temperature", "type": "standard_name", "name": "sea_ice_temperature", "description": "Sea ice temperature is the bulk temperature of the sea ice, not the surface (skin) temperature. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_ice_temperature_expressed_as_heat_content.json b/data_descriptors/standard_name/sea_ice_temperature_expressed_as_heat_content.json index 5cbf7728a..0fce65fbf 100644 --- a/data_descriptors/standard_name/sea_ice_temperature_expressed_as_heat_content.json +++ b/data_descriptors/standard_name/sea_ice_temperature_expressed_as_heat_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_temperature_expressed_as_heat_content", + "id": "sea_ice_temperature_expressed_as_heat_content", "type": "standard_name", "name": "sea_ice_temperature_expressed_as_heat_content", "description": "The quantity with standard name sea_ice_temperature_expressed_as_heat_content is calculated relative to the heat content of ice at zero degrees Celsius, which is assumed to have a heat content of zero Joules. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea ice multiplied by the temperature of the sea ice in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea ice the integral is assumed to be calculated over the full depth of the ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_thickness.json b/data_descriptors/standard_name/sea_ice_thickness.json index 53a817730..75dd2c33c 100644 --- a/data_descriptors/standard_name/sea_ice_thickness.json +++ b/data_descriptors/standard_name/sea_ice_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_thickness", + "id": "sea_ice_thickness", "type": "standard_name", "name": "sea_ice_thickness", "description": "\"Thickness\" means the vertical extent of a layer. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_transport_across_line.json b/data_descriptors/standard_name/sea_ice_transport_across_line.json index 1505a9a95..c27314589 100644 --- a/data_descriptors/standard_name/sea_ice_transport_across_line.json +++ b/data_descriptors/standard_name/sea_ice_transport_across_line.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_transport_across_line", + "id": "sea_ice_transport_across_line", "type": "standard_name", "name": "sea_ice_transport_across_line", "description": "Transport across_line means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_volume.json b/data_descriptors/standard_name/sea_ice_volume.json index 374f89c1d..6eb63be1d 100644 --- a/data_descriptors/standard_name/sea_ice_volume.json +++ b/data_descriptors/standard_name/sea_ice_volume.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_volume", + "id": "sea_ice_volume", "type": "standard_name", "name": "sea_ice_volume", "description": "\"X_volume\" means the volume occupied by X within the grid cell. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_x_displacement.json b/data_descriptors/standard_name/sea_ice_x_displacement.json index ca260ba6e..5ede035eb 100644 --- a/data_descriptors/standard_name/sea_ice_x_displacement.json +++ b/data_descriptors/standard_name/sea_ice_x_displacement.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_x_displacement", + "id": "sea_ice_x_displacement", "type": "standard_name", "name": "sea_ice_x_displacement", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Displacement\" means the change in geospatial position of an object that has moved over time. If possible, the time interval over which the motion took place should be specified using a bounds variable for the time coordinate variable. A displacement can be represented as a vector. Such a vector should however not be interpreted as describing a rectilinear, constant speed motion but merely as an indication that the start point of the vector is found at the tip of the vector after the time interval associated with the displacement variable. A displacement does not prescribe a trajectory. Sea ice displacement can be defined as a two-dimensional vector, with no vertical component. An x displacement is calculated from the difference in the moving object's grid x coordinate between the start and end of the time interval associated with the displacement variable. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_coriolis_effect.json b/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_coriolis_effect.json index 9a3863ae5..c1ff4cff2 100644 --- a/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_coriolis_effect.json +++ b/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_coriolis_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_x_force_per_unit_area_due_to_coriolis_effect", + "id": "sea_ice_x_force_per_unit_area_due_to_coriolis_effect", "type": "standard_name", "name": "sea_ice_x_force_per_unit_area_due_to_coriolis_effect", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In meteorology and oceanography, the Coriolis effect per unit mass arises solely from the earth's rotation and acts as a deflecting force, normal to the velocity, to the right of the motion in the Northern Hemisphere and to the left in the Southern Hemisphere. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Coriolis_force. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt.json b/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt.json index 537bdf68b..06681d65d 100644 --- a/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt.json +++ b/data_descriptors/standard_name/sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt", + "id": "sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt", "type": "standard_name", "name": "sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Several factors contribute to differences in the ocean surface level, including uneven heating, salinity variations, and currents, especially near coastal regions or ice shelves. Differences in surface level result in sea-surface tilt, a force that influences the ice motion. Reference: National Snow and Ice Data Center https://nsidc.org/cryosphere/seaice/processes/dynamics.html. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_x_internal_stress.json b/data_descriptors/standard_name/sea_ice_x_internal_stress.json index c090fbdc3..e2b30885d 100644 --- a/data_descriptors/standard_name/sea_ice_x_internal_stress.json +++ b/data_descriptors/standard_name/sea_ice_x_internal_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_x_internal_stress", + "id": "sea_ice_x_internal_stress", "type": "standard_name", "name": "sea_ice_x_internal_stress", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. Internal ice stress is a measure of the compactness, or strength, of the ice. Internal ice stress usually acts as a resistance to the motion caused by the wind force. Reference: National Snow and Ice Data Center https://nsidc.org/cryosphere/seaice/processes/dynamics.html. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_x_transport.json b/data_descriptors/standard_name/sea_ice_x_transport.json index afe6493df..648fd1f85 100644 --- a/data_descriptors/standard_name/sea_ice_x_transport.json +++ b/data_descriptors/standard_name/sea_ice_x_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_x_transport", + "id": "sea_ice_x_transport", "type": "standard_name", "name": "sea_ice_x_transport", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_x_velocity.json b/data_descriptors/standard_name/sea_ice_x_velocity.json index ccfa754cd..9f552ef3b 100644 --- a/data_descriptors/standard_name/sea_ice_x_velocity.json +++ b/data_descriptors/standard_name/sea_ice_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_x_velocity", + "id": "sea_ice_x_velocity", "type": "standard_name", "name": "sea_ice_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_y_displacement.json b/data_descriptors/standard_name/sea_ice_y_displacement.json index f2c39dc6a..61437b8a1 100644 --- a/data_descriptors/standard_name/sea_ice_y_displacement.json +++ b/data_descriptors/standard_name/sea_ice_y_displacement.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_y_displacement", + "id": "sea_ice_y_displacement", "type": "standard_name", "name": "sea_ice_y_displacement", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Displacement\" means the change in geospatial position of an object that has moved over time. If possible, the time interval over which the motion took place should be specified using a bounds variable for the time coordinate variable. A displacement can be represented as a vector. Such a vector should however not be interpreted as describing a rectilinear, constant speed motion but merely as an indication that the start point of the vector is found at the tip of the vector after the time interval associated with the displacement variable. A displacement does not prescribe a trajectory. Sea ice displacement can be defined as a two-dimensional vector, with no vertical component. A y displacement is calculated from the difference in the moving object's grid y coordinate between the start and end of the time interval associated with the displacement variable. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_coriolis_effect.json b/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_coriolis_effect.json index 45a8ded1b..fc672a8b8 100644 --- a/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_coriolis_effect.json +++ b/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_coriolis_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_y_force_per_unit_area_due_to_coriolis_effect", + "id": "sea_ice_y_force_per_unit_area_due_to_coriolis_effect", "type": "standard_name", "name": "sea_ice_y_force_per_unit_area_due_to_coriolis_effect", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In meteorology and oceanography, the Coriolis effect per unit mass arises solely from the earth's rotation and acts as a deflecting force, normal to the velocity, to the right of the motion in the Northern Hemisphere and to the left in the Southern Hemisphere. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Coriolis_force. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt.json b/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt.json index 5a07fe934..7e5992058 100644 --- a/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt.json +++ b/data_descriptors/standard_name/sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt", + "id": "sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt", "type": "standard_name", "name": "sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Several factors contribute to differences in the ocean surface level, including uneven heating, salinity variations, and currents, especially near coastal regions or ice shelves. Differences in surface level result in sea-surface tilt, a force that influences the ice motion. Reference: National Snow and Ice Data Center https://nsidc.org/cryosphere/seaice/processes/dynamics.html. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_y_internal_stress.json b/data_descriptors/standard_name/sea_ice_y_internal_stress.json index b0e17c0cb..2c1710564 100644 --- a/data_descriptors/standard_name/sea_ice_y_internal_stress.json +++ b/data_descriptors/standard_name/sea_ice_y_internal_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_y_internal_stress", + "id": "sea_ice_y_internal_stress", "type": "standard_name", "name": "sea_ice_y_internal_stress", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. Internal ice stress is a measure of the compactness, or strength, of the ice. Internal ice stress usually acts as a resistance to the motion caused by the wind force. Reference: National Snow and Ice Data Center https://nsidc.org/cryosphere/seaice/processes/dynamics.html. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_y_transport.json b/data_descriptors/standard_name/sea_ice_y_transport.json index e439d3205..ef5755aa6 100644 --- a/data_descriptors/standard_name/sea_ice_y_transport.json +++ b/data_descriptors/standard_name/sea_ice_y_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_y_transport", + "id": "sea_ice_y_transport", "type": "standard_name", "name": "sea_ice_y_transport", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_ice_y_velocity.json b/data_descriptors/standard_name/sea_ice_y_velocity.json index 70c123161..0f0a96f00 100644 --- a/data_descriptors/standard_name/sea_ice_y_velocity.json +++ b/data_descriptors/standard_name/sea_ice_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_ice_y_velocity", + "id": "sea_ice_y_velocity", "type": "standard_name", "name": "sea_ice_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/sea_surface_density.json b/data_descriptors/standard_name/sea_surface_density.json index b0369040f..51a9f8f3f 100644 --- a/data_descriptors/standard_name/sea_surface_density.json +++ b/data_descriptors/standard_name/sea_surface_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_density", + "id": "sea_surface_density", "type": "standard_name", "name": "sea_surface_density", "description": "Sea surface density is the density of sea water near the surface (including the part under sea-ice, if any).", diff --git a/data_descriptors/standard_name/sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves.json b/data_descriptors/standard_name/sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves.json index b91bfa52c..b9c9385aa 100644 --- a/data_descriptors/standard_name/sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves.json +++ b/data_descriptors/standard_name/sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves", + "id": "sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves", "type": "standard_name", "name": "sea_surface_downward_eastward_stress_due_to_dissipation_of_sea_surface_waves", "description": "The surface called \"sea surface\" means the upper boundary of the ocean. \"Surface stress\" means the shear stress (force per unit area) exerted at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, surface stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Eastward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"dissipation_of_sea_surface_waves\" means the stress associated with sea surface waves dissipation processes such as whitecapping.", diff --git a/data_descriptors/standard_name/sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves.json b/data_descriptors/standard_name/sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves.json index edf044f43..94744ba39 100644 --- a/data_descriptors/standard_name/sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves.json +++ b/data_descriptors/standard_name/sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves", + "id": "sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves", "type": "standard_name", "name": "sea_surface_downward_northward_stress_due_to_dissipation_of_sea_surface_waves", "description": "The surface called \"sea surface\" means the upper boundary of the ocean. \"Surface stress\" means the shear stress (force per unit area) exerted at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, surface stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"dissipation_of_sea_surface_waves\" means the stress associated with sea surface waves dissipation processes such as whitecapping.", diff --git a/data_descriptors/standard_name/sea_surface_foundation_temperature.json b/data_descriptors/standard_name/sea_surface_foundation_temperature.json index b41637eb9..2d7aad265 100644 --- a/data_descriptors/standard_name/sea_surface_foundation_temperature.json +++ b/data_descriptors/standard_name/sea_surface_foundation_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_foundation_temperature", + "id": "sea_surface_foundation_temperature", "type": "standard_name", "name": "sea_surface_foundation_temperature", "description": "The sea surface foundation temperature is the water temperature that is not influenced by a thermally stratified layer of diurnal temperature variability (either by daytime warming or nocturnal cooling). The foundation temperature is named to indicate that it is the temperature from which the growth of the diurnal thermocline develops each day, noting that on some occasions with a deep mixed layer there is no clear foundation temperature in the surface layer. In general, sea surface foundation temperature will be similar to a night time minimum or pre-dawn value at depths of between approximately 1 and 5 meters. In the absence of any diurnal signal, the foundation temperature is considered equivalent to the quantity with standard name sea_surface_subskin_temperature. The sea surface foundation temperature defines a level in the upper water column that varies in depth, space, and time depending on the local balance between thermal stratification and turbulent energy and is expected to change slowly over the course of a day. If possible, a data variable with the standard name sea_surface_foundation_temperature should be used with a scalar vertical coordinate variable to specify the depth of the foundation level. Sea surface foundation temperature is measured at the base of the diurnal thermocline or as close to the water surface as possible in the absence of thermal stratification. Only in situ contact thermometry is able to measure the sea surface foundation temperature. Analysis procedures must be used to estimate sea surface foundation temperature value from radiometric satellite measurements of the quantities with standard names sea_surface_skin_temperature and sea_surface_subskin_temperature. Sea surface foundation temperature provides a connection with the historical concept of a \"bulk\" sea surface temperature considered representative of the oceanic mixed layer temperature that is typically represented by any sea temperature measurement within the upper ocean over a depth range of 1 to approximately 20 meters. The general term, \"bulk\" sea surface temperature, has the standard name sea_surface_temperature with no associated vertical coordinate axis. Sea surface foundation temperature provides a more precise, well defined quantity than \"bulk\" sea surface temperature and, consequently, is more representative of the mixed layer temperature. The temperature of sea water at a particular depth (other than the foundation level) should be reported using the standard name sea_water_temperature and, wherever possible, supplying a vertical coordinate axis or scalar coordinate variable. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_surface_height_above_geoid.json b/data_descriptors/standard_name/sea_surface_height_above_geoid.json index 9c1bb4832..ca80de4cd 100644 --- a/data_descriptors/standard_name/sea_surface_height_above_geoid.json +++ b/data_descriptors/standard_name/sea_surface_height_above_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_above_geoid", + "id": "sea_surface_height_above_geoid", "type": "standard_name", "name": "sea_surface_height_above_geoid", "description": "\"Height_above_X\" means the vertical distance above the named surface X. \"Sea surface height\" is a time-varying quantity. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention. By definition of the geoid, the global average of the time-mean sea surface height (i.e. mean sea level) above the geoid must be zero. The standard name for the height of the sea surface above mean sea level is sea_surface_height_above_mean_sea_level. The standard name for the height of the sea surface above the reference ellipsoid is sea_surface_height_above_reference_ellipsoid.", diff --git a/data_descriptors/standard_name/sea_surface_height_above_geopotential_datum.json b/data_descriptors/standard_name/sea_surface_height_above_geopotential_datum.json index 2a3cb24ea..f987e7abd 100644 --- a/data_descriptors/standard_name/sea_surface_height_above_geopotential_datum.json +++ b/data_descriptors/standard_name/sea_surface_height_above_geopotential_datum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_above_geopotential_datum", + "id": "sea_surface_height_above_geopotential_datum", "type": "standard_name", "name": "sea_surface_height_above_geopotential_datum", "description": "\"Height_above_X\" means the vertical distance above the named surface X. \"Sea surface height\" is a time-varying quantity. The \"geopotential datum\" is any estimated surface of constant geopotential used as a datum i.e. a reference level; for the geoid as a datum, specific standard names are available. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/sea_surface_height_above_mean_sea_level.json b/data_descriptors/standard_name/sea_surface_height_above_mean_sea_level.json index b8dac9e9d..552a2dbfe 100644 --- a/data_descriptors/standard_name/sea_surface_height_above_mean_sea_level.json +++ b/data_descriptors/standard_name/sea_surface_height_above_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_above_mean_sea_level", + "id": "sea_surface_height_above_mean_sea_level", "type": "standard_name", "name": "sea_surface_height_above_mean_sea_level", "description": "\"Sea surface height\" is a time-varying quantity. \"Height_above_X\" means the vertical distance above the named surface X. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The standard name for the height of the sea surface above the geoid is sea_surface_height_above_geoid. The standard name for the height of the sea surface above the reference ellipsoid is sea_surface_height_above_reference_ellipsoid.", diff --git a/data_descriptors/standard_name/sea_surface_height_above_reference_ellipsoid.json b/data_descriptors/standard_name/sea_surface_height_above_reference_ellipsoid.json index a18cebba7..d01e212e4 100644 --- a/data_descriptors/standard_name/sea_surface_height_above_reference_ellipsoid.json +++ b/data_descriptors/standard_name/sea_surface_height_above_reference_ellipsoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_above_reference_ellipsoid", + "id": "sea_surface_height_above_reference_ellipsoid", "type": "standard_name", "name": "sea_surface_height_above_reference_ellipsoid", "description": "\"Height_above_X\" means the vertical distance above the named surface X. \"Sea surface height\" is a time-varying quantity. A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention. The standard name for the height of the sea surface above the geoid is sea_surface_height_above_geoid. The standard name for the height of the sea surface above mean sea level is sea_surface_height_above_mean_sea_level.", diff --git a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_earth_tide.json b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_earth_tide.json index 309f108a7..9f010ea96 100644 --- a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_earth_tide.json +++ b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_earth_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_amplitude_due_to_earth_tide", + "id": "sea_surface_height_amplitude_due_to_earth_tide", "type": "standard_name", "name": "sea_surface_height_amplitude_due_to_earth_tide", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are a significant contributor to the observed sea surface height; earth tide means the solid earth tide.", diff --git a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_equilibrium_ocean_tide.json b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_equilibrium_ocean_tide.json index a7937fd7c..eef374b47 100644 --- a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_equilibrium_ocean_tide.json +++ b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_equilibrium_ocean_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_amplitude_due_to_equilibrium_ocean_tide", + "id": "sea_surface_height_amplitude_due_to_equilibrium_ocean_tide", "type": "standard_name", "name": "sea_surface_height_amplitude_due_to_equilibrium_ocean_tide", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are a significant contributor to the observed sea surface height; equilibrium ocean tide refers to the long period ocean tide.", diff --git a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_geocentric_ocean_tide.json b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_geocentric_ocean_tide.json index f915901cd..e36239432 100644 --- a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_geocentric_ocean_tide.json +++ b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_geocentric_ocean_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_amplitude_due_to_geocentric_ocean_tide", + "id": "sea_surface_height_amplitude_due_to_geocentric_ocean_tide", "type": "standard_name", "name": "sea_surface_height_amplitude_due_to_geocentric_ocean_tide", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are a significant contributor to the observed sea surface height; geocentric ocean tide means the sum total of ocean tide and load tide.", diff --git a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide.json b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide.json index 65e0c0cfa..c71430fa9 100644 --- a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide.json +++ b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide", + "id": "sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide", "type": "standard_name", "name": "sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are a significant contributor to the observed sea surface height; non equilibrium ocean tide refers to the long period ocean tide.", diff --git a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_pole_tide.json b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_pole_tide.json index 418f10f36..8e325608e 100644 --- a/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_pole_tide.json +++ b/data_descriptors/standard_name/sea_surface_height_amplitude_due_to_pole_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_amplitude_due_to_pole_tide", + "id": "sea_surface_height_amplitude_due_to_pole_tide", "type": "standard_name", "name": "sea_surface_height_amplitude_due_to_pole_tide", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are a significant contributor to the observed sea surface height; the pole tide occurs due to variations in the earth's rotation.", diff --git a/data_descriptors/standard_name/sea_surface_height_bias_due_to_sea_surface_roughness.json b/data_descriptors/standard_name/sea_surface_height_bias_due_to_sea_surface_roughness.json index 517d0db87..5aedc9d0f 100644 --- a/data_descriptors/standard_name/sea_surface_height_bias_due_to_sea_surface_roughness.json +++ b/data_descriptors/standard_name/sea_surface_height_bias_due_to_sea_surface_roughness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_bias_due_to_sea_surface_roughness", + "id": "sea_surface_height_bias_due_to_sea_surface_roughness", "type": "standard_name", "name": "sea_surface_height_bias_due_to_sea_surface_roughness", "description": "Altimeter pulses tend to be more strongly reflected by the troughs of sea surface waves than by the crests leading to a bias in the measured sea surface height. This quantity is commonly known as \"sea state bias\". \"Sea surface height\" is a time-varying quantity. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.json b/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.json index ffb4b407f..c024eccbf 100644 --- a/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.json +++ b/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency", + "id": "sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency", "type": "standard_name", "name": "sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Air pressure and wind at high frequency\" means variations in air pressure with periods shorter than 20 days. These give rise to corresponding variations in sea surface topography. The quantity sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency should be applied by adding it to the quantity with standard name altimeter_range. Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_dry_troposphere, altimeter_range_correction_due_to_ionosphere and sea_surface_height_correction_due_to_air_pressure_at_low_frequency.", diff --git a/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_at_low_frequency.json b/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_at_low_frequency.json index ed79855a5..8e93fddb5 100644 --- a/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_at_low_frequency.json +++ b/data_descriptors/standard_name/sea_surface_height_correction_due_to_air_pressure_at_low_frequency.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_height_correction_due_to_air_pressure_at_low_frequency", + "id": "sea_surface_height_correction_due_to_air_pressure_at_low_frequency", "type": "standard_name", "name": "sea_surface_height_correction_due_to_air_pressure_at_low_frequency", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Air pressure at low frequency\" means variations in air pressure with periods longer than 20 days. These give rise to corresponding variations in sea surface topography. The quantity sea_surface_height_correction_due_to_air_pressure_at_low_frequency is commonly called the \"inverted barometer effect\" and the correction should be applied by adding it to the quantity with standard name altimeter_range. Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_dry_troposphere, altimeter_range_correction_due_to_ionosphere and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.", diff --git a/data_descriptors/standard_name/sea_surface_infragravity_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_infragravity_wave_significant_height.json index d546a1510..b50cd4200 100644 --- a/data_descriptors/standard_name/sea_surface_infragravity_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_infragravity_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_infragravity_wave_significant_height", + "id": "sea_surface_infragravity_wave_significant_height", "type": "standard_name", "name": "sea_surface_infragravity_wave_significant_height", "description": "Significant wave height is a statistic computed from wave measurements and corresponds to the average height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest. Infragravity waves are waves occurring in the frequency range 0.04 to 0.004 s^-1 (wave periods of 25 to 250 seconds).", diff --git a/data_descriptors/standard_name/sea_surface_mean_square_crosswave_slope.json b/data_descriptors/standard_name/sea_surface_mean_square_crosswave_slope.json index ece9c9444..cc98050a8 100644 --- a/data_descriptors/standard_name/sea_surface_mean_square_crosswave_slope.json +++ b/data_descriptors/standard_name/sea_surface_mean_square_crosswave_slope.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_mean_square_crosswave_slope", + "id": "sea_surface_mean_square_crosswave_slope", "type": "standard_name", "name": "sea_surface_mean_square_crosswave_slope", "description": "Wave slope describes an aspect of sea surface wave geometry related to sea surface roughness. Mean square slope describes a derivation over multiple waves within a sea-state, for example calculated from moments of the wave directional spectrum. The phrase \"crosswave_slope\" means that slope values are derived from vector components across (normal to) the axis from which waves are travelling. The primary directional axis along which wave energy associated with the slope calculation is travelling has the standard name sea_surface_mean_square_upwave_slope_direction.", diff --git a/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope.json b/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope.json index eaaa477d7..e8103d309 100644 --- a/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope.json +++ b/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_mean_square_upwave_slope", + "id": "sea_surface_mean_square_upwave_slope", "type": "standard_name", "name": "sea_surface_mean_square_upwave_slope", "description": "Wave slope describes an aspect of sea surface wave geometry related to sea surface roughness. Mean square slope describes a derivation over multiple waves within a sea-state, for example calculated from moments of the wave directional spectrum. The phrase \"upwave_slope\" means that slope values are derived from vector components along (parallel to) the axis from which waves are travelling. The primary directional axis along which wave energy associated with the slope calculation is travelling has the standard name sea_surface_mean_square_upwave_slope_direction.", diff --git a/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope_direction.json b/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope_direction.json index e17046dba..cdb48675f 100644 --- a/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope_direction.json +++ b/data_descriptors/standard_name/sea_surface_mean_square_upwave_slope_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_mean_square_upwave_slope_direction", + "id": "sea_surface_mean_square_upwave_slope_direction", "type": "standard_name", "name": "sea_surface_mean_square_upwave_slope_direction", "description": "Wave slope describes an aspect of sea surface wave geometry related to sea surface roughness. Mean square slope describes a derivation over multiple waves within a sea-state, for example calculated from moments of the wave directional spectrum. The phrase \"upwave_slope_direction\" is used to assign a primary directional axis along which wave energy associated with the slope calculation is travelling; \"upwave\" is equivalent to \"from_direction\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_directional_spread.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_directional_spread.json index 4d3915ee5..21d2f574b 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_directional_spread.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_directional_spread.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_directional_spread", + "id": "sea_surface_primary_swell_wave_directional_spread", "type": "standard_name", "name": "sea_surface_primary_swell_wave_directional_spread", "description": "The quantity with standard name sea_surface_primary_swell_wave_directional_spread is the directional width of the primary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave. Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum.json index d4f950080..df1620bd0 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum", + "id": "sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_primary_swell_wave_energy_at_variance_spectral_density_maximum is the energy of the most energetic waves within the primary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave. The phrase \"wave_energy_at_variance_spectral_density_maximum\", sometimes called peak wave energy, describes the maximum value of the wave_variance_spectral_density within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction.json index 3ac96d0f1..396d2f203 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_from_direction", + "id": "sea_surface_primary_swell_wave_from_direction", "type": "standard_name", "name": "sea_surface_primary_swell_wave_from_direction", "description": "The quantity with standard name sea_surface_primary_swell_wave_from_direction is the direction from which the most energetic swell waves are coming. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum.json index fbdd3dc90..17a9d23a3 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum", + "id": "sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_primary_swell_wave_from_direction_at_variance_spectral_density_maximum is the direction from which the most energetic waves are coming in the primary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave in the low frequency portion of a bimodal wave frequency spectrum. The spectral peak is the most energetic wave in the wave spectrum partition. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_mean_period.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_mean_period.json index 9c9fc7510..787c25d08 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_mean_period.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_mean_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_mean_period", + "id": "sea_surface_primary_swell_wave_mean_period", "type": "standard_name", "name": "sea_surface_primary_swell_wave_mean_period", "description": "The quantity with standard name sea_surface_primary_swell_wave_mean_period is the mean period of the most energetic swell waves. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. Wave mean period is the mean period measured over the observation duration.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum.json index 39467d70f..f32553d4e 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum", + "id": "sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_primary_swell_wave_period_at_variance_spectral_density_maximum is the period of the most energetic waves within the primary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. The phrase \"wave_period_at_variance_spectral_density_maximum\", sometimes called peak wave period, describes the period of the most energetic waves within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_primary_swell_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_primary_swell_wave_significant_height.json index cb973f8f8..a7571649a 100644 --- a/data_descriptors/standard_name/sea_surface_primary_swell_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_primary_swell_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_primary_swell_wave_significant_height", + "id": "sea_surface_primary_swell_wave_significant_height", "type": "standard_name", "name": "sea_surface_primary_swell_wave_significant_height", "description": "Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The primary swell wave is the most energetic swell wave. Significant wave height is a statistic computed from wave measurements and corresponds to the average height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest.", diff --git a/data_descriptors/standard_name/sea_surface_salinity.json b/data_descriptors/standard_name/sea_surface_salinity.json index ba7ea3bcf..1d3bfb357 100644 --- a/data_descriptors/standard_name/sea_surface_salinity.json +++ b/data_descriptors/standard_name/sea_surface_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_salinity", + "id": "sea_surface_salinity", "type": "standard_name", "name": "sea_surface_salinity", "description": "Sea surface salinity is the salt content of sea water close to the sea surface, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. Sea surface salinity is often abbreviated as \"SSS\". For the salinity of sea water at a particular depth or layer, a data variable of \"sea_water_salinity\" or one of the more precisely defined salinities should be used with a vertical coordinate axis. There are standard names for the precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_directional_spread.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_directional_spread.json index 6a312e42d..c1d598b2f 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_directional_spread.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_directional_spread.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_directional_spread", + "id": "sea_surface_secondary_swell_wave_directional_spread", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_directional_spread", "description": "The quantity with standard name sea_surface_secondary_swell_wave_directional_spread is the directional width of the secondary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum.json index b19af39ed..5ffc3d625 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum", + "id": "sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_secondary_swell_wave_energy_at_variance_spectral_density_maximum is the energy of the most energetic waves within the secondary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. The phrase \"wave_energy_at_variance_spectral_density_maximum\", sometimes called peak wave energy, describes the maximum value of the wave_variance_spectral_density within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction.json index 3d3cb05bb..c30c270ea 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_from_direction", + "id": "sea_surface_secondary_swell_wave_from_direction", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_from_direction", "description": "The quantity with standard name sea_surface_secondary_swell_wave_from_direction is the direction from which the second most energetic swell waves are coming. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum.json index a1948cfd9..a56679db3 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum", + "id": "sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_secondary_swell_wave_from_direction_at_variance_spectral_density_maximum is the direction from which the most energetic waves are coming in the secondary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. The spectral peak is the most energetic wave in the wave spectrum partition. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_mean_period.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_mean_period.json index 53bf4c4c1..876424efb 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_mean_period.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_mean_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_mean_period", + "id": "sea_surface_secondary_swell_wave_mean_period", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_mean_period", "description": "The quantity with standard name sea_surface_secondary_swell_wave_mean_period is the mean period of the second most energetic swell waves. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. Wave mean period is the mean period measured over the observation duration.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum.json index 026ae152e..d7a31f45c 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum", + "id": "sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_secondary_swell_wave_period_at_variance_spectral_density_maximum is the period of the most energetic waves within the secondary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. The phrase \"wave_period_at_variance_spectral_density_maximum\", sometimes called peak wave period, describes the period of the most energetic waves within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_significant_height.json index 841858095..dd998fb5b 100644 --- a/data_descriptors/standard_name/sea_surface_secondary_swell_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_secondary_swell_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_secondary_swell_wave_significant_height", + "id": "sea_surface_secondary_swell_wave_significant_height", "type": "standard_name", "name": "sea_surface_secondary_swell_wave_significant_height", "description": "Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The secondary swell wave is the second most energetic wave in the low frequency portion of a bimodal wave frequency spectrum. Significant wave height is a statistic computed from wave measurements and corresponds to the average height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest.", diff --git a/data_descriptors/standard_name/sea_surface_skin_temperature.json b/data_descriptors/standard_name/sea_surface_skin_temperature.json index e227dd446..64d16e0ff 100644 --- a/data_descriptors/standard_name/sea_surface_skin_temperature.json +++ b/data_descriptors/standard_name/sea_surface_skin_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_skin_temperature", + "id": "sea_surface_skin_temperature", "type": "standard_name", "name": "sea_surface_skin_temperature", "description": "The sea surface skin temperature is the temperature measured by an infrared radiometer typically operating at wavelengths in the range 3.7 - 12 micrometers. It represents the temperature within the conductive diffusion-dominated sub-layer at a depth of approximately 10 - 20 micrometers below the air-sea interface. Measurements of this quantity are subject to a large potential diurnal cycle including cool skin layer effects (especially at night under clear skies and low wind speed conditions) and warm layer effects in the daytime. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_surface_subskin_temperature.json b/data_descriptors/standard_name/sea_surface_subskin_temperature.json index 3cc58bf39..12fa67729 100644 --- a/data_descriptors/standard_name/sea_surface_subskin_temperature.json +++ b/data_descriptors/standard_name/sea_surface_subskin_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_subskin_temperature", + "id": "sea_surface_subskin_temperature", "type": "standard_name", "name": "sea_surface_subskin_temperature", "description": "The sea surface subskin temperature is the temperature at the base of the conductive laminar sub-layer of the ocean surface, that is, at a depth of approximately 1 - 1.5 millimeters below the air-sea interface. For practical purposes, this quantity can be well approximated to the measurement of surface temperature by a microwave radiometer operating in the 6 - 11 gigahertz frequency range, but the relationship is neither direct nor invariant to changing physical conditions or to the specific geometry of the microwave measurements. Measurements of this quantity are subject to a large potential diurnal cycle due to thermal stratification of the upper ocean layer in low wind speed high solar irradiance conditions. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_directional_spread.json b/data_descriptors/standard_name/sea_surface_swell_wave_directional_spread.json index b54378e08..d4916c15c 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_directional_spread.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_directional_spread.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_directional_spread", + "id": "sea_surface_swell_wave_directional_spread", "type": "standard_name", "name": "sea_surface_swell_wave_directional_spread", "description": "The quantity with standard name sea_surface_swell_wave_directional_spread is the directional width of the swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_from_direction.json b/data_descriptors/standard_name/sea_surface_swell_wave_from_direction.json index 9c340a23e..a69ac6661 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_from_direction", + "id": "sea_surface_swell_wave_from_direction", "type": "standard_name", "name": "sea_surface_swell_wave_from_direction", "description": "Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum.json index 50912b0b1..1f70faa93 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum", + "id": "sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_swell_wave_from_direction_at_variance_spectral_density_maximum is the direction from which the most energetic waves are coming in the swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The spectral peak is the most energetic wave in the wave spectrum partition. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The swell wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period.json b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period.json index 34b418a47..cfe1e3451 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_mean_period", + "id": "sea_surface_swell_wave_mean_period", "type": "standard_name", "name": "sea_surface_swell_wave_mean_period", "description": "A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. Wave mean period is the mean period measured over the observation duration. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json index 83a26f22a..26ab845e7 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment", + "id": "sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment", "type": "standard_name", "name": "sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment", "description": "The swell wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S can be integrated over direction to give S1= integral(S dtheta). Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The first wave period, T(m1), is calculated as the ratio M(0)/M(1).", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json index 67b532717..5a56efd5a 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", + "id": "sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", "type": "standard_name", "name": "sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", "description": "The swell wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S can be integrated over direction to give S1= integral(S dtheta). Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The inverse wave period, T(m-1), is calculated as the ratio M(-1)/M(0).", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json index 6337dafd1..e41cc26b4 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment", + "id": "sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment", "type": "standard_name", "name": "sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment", "description": "The swell wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S can be integrated over direction to give S1= integral(S dtheta). Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The second wave period, T(m2), is calculated as the square root of the ratio M(0)/M(2).", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_period.json b/data_descriptors/standard_name/sea_surface_swell_wave_period.json index 678d51f08..9f7ed982c 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_period.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_period", + "id": "sea_surface_swell_wave_period", "type": "standard_name", "name": "sea_surface_swell_wave_period", "description": "A period is an interval of time, or the time-period of an oscillation. Swell waves are waves on the ocean surface.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_period_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_swell_wave_period_at_variance_spectral_density_maximum.json index ad5bcc27b..721760b8f 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_period_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_period_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_period_at_variance_spectral_density_maximum", + "id": "sea_surface_swell_wave_period_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_swell_wave_period_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_swell_wave_period_at_variance_spectral_density_maximum is the period of the most energetic waves within the swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. The phrase \"wave_period_at_variance_spectral_density_maximum\", sometimes called peak wave period, describes the period of the most energetic waves within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_swell_wave_significant_height.json index 2ccfd4451..8819a5c4e 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_significant_height", + "id": "sea_surface_swell_wave_significant_height", "type": "standard_name", "name": "sea_surface_swell_wave_significant_height", "description": "Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. Significant wave height is a statistic computed from wave measurements and corresponds to the average height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest.", diff --git a/data_descriptors/standard_name/sea_surface_swell_wave_to_direction.json b/data_descriptors/standard_name/sea_surface_swell_wave_to_direction.json index 7f961765f..bc3d3e1f1 100644 --- a/data_descriptors/standard_name/sea_surface_swell_wave_to_direction.json +++ b/data_descriptors/standard_name/sea_surface_swell_wave_to_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_swell_wave_to_direction", + "id": "sea_surface_swell_wave_to_direction", "type": "standard_name", "name": "sea_surface_swell_wave_to_direction", "description": "Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_temperature.json b/data_descriptors/standard_name/sea_surface_temperature.json index 228154bfb..aa2d665f2 100644 --- a/data_descriptors/standard_name/sea_surface_temperature.json +++ b/data_descriptors/standard_name/sea_surface_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_temperature", + "id": "sea_surface_temperature", "type": "standard_name", "name": "sea_surface_temperature", "description": "Sea surface temperature is usually abbreviated as \"SST\". It is the temperature of sea water near the surface (including the part under sea-ice, if any). More specific terms, namely sea_surface_skin_temperature, sea_surface_subskin_temperature, and surface_temperature are available for the skin, subskin, and interface temperature. respectively. For the temperature of sea water at a particular depth or layer, a data variable of sea_water_temperature with a vertical coordinate axis should be used. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_directional_spread.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_directional_spread.json index d8941c401..b22b15e60 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_directional_spread.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_directional_spread.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_directional_spread", + "id": "sea_surface_tertiary_swell_wave_directional_spread", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_directional_spread", "description": "The quantity with standard name sea_surface_tertiary_swell_wave_directional_spread is the directional width of the tertiary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave. Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum.json index 88e50a643..73f83d798 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum", + "id": "sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_tertiary_swell_wave_energy_at_variance_spectral_density_maximum is the energy of the most energetic waves within the tertiary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave. The phrase \"wave_energy_at_variance_spectral_density_maximum\", sometimes called peak wave energy, describes the maximum value of the wave_variance_spectral_density within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction.json index f0c906858..717285212 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_from_direction", + "id": "sea_surface_tertiary_swell_wave_from_direction", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_from_direction", "description": "The quantity with standard name sea_surface_tertiary_swell_wave_from_direction is the direction from which the third most energetic swell waves are coming. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum.json index 41c5930f1..1d977fbd1 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum", + "id": "sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_tertiary_swell_wave_from_direction_at_variance_spectral_density_maximum is the direction from which the most energetic waves are coming in the tertiary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave in the low frequency portion of a bimodal wave frequency spectrum. The spectral peak is the most energetic wave in the wave spectrum partition. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_mean_period.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_mean_period.json index 30d165c4b..0bcfa6c16 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_mean_period.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_mean_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_mean_period", + "id": "sea_surface_tertiary_swell_wave_mean_period", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_mean_period", "description": "The quantity with standard name sea_surface_tertiary_swell_wave_mean_period is the mean period of the third most energetic swell waves. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. Wave mean period is the mean period measured over the observation duration.", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum.json index 83d0a6cf2..795f119f5 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum", + "id": "sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_tertiary_swell_wave_period_at_variance_spectral_density_maximum is the period of the most energetic waves within the tertiary swell wave component of a sea. Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. The phrase \"wave_period_at_variance_spectral_density_maximum\", sometimes called peak wave period, describes the period of the most energetic waves within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_significant_height.json index 262fa7f17..164ce8d9c 100644 --- a/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_tertiary_swell_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_tertiary_swell_wave_significant_height", + "id": "sea_surface_tertiary_swell_wave_significant_height", "type": "standard_name", "name": "sea_surface_tertiary_swell_wave_significant_height", "description": "Swell waves are waves on the ocean surface and are the low frequency portion of a bimodal wave frequency spectrum. The tertiary swell wave is the third most energetic swell wave. Significant wave height is a statistic computed from wave measurements and corresponds to the mean height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest.", diff --git a/data_descriptors/standard_name/sea_surface_wave_directional_spread.json b/data_descriptors/standard_name/sea_surface_wave_directional_spread.json index dc60587d7..5b1ee325b 100644 --- a/data_descriptors/standard_name/sea_surface_wave_directional_spread.json +++ b/data_descriptors/standard_name/sea_surface_wave_directional_spread.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_directional_spread", + "id": "sea_surface_wave_directional_spread", "type": "standard_name", "name": "sea_surface_wave_directional_spread", "description": "Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wave_directional_spread_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wave_directional_spread_at_variance_spectral_density_maximum.json index 5a42c5437..0e8efb47f 100644 --- a/data_descriptors/standard_name/sea_surface_wave_directional_spread_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wave_directional_spread_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_directional_spread_at_variance_spectral_density_maximum", + "id": "sea_surface_wave_directional_spread_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wave_directional_spread_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_wave_directional_spread_at_variance_spectral_density_maximum is the directional spread of the most energetic waves. Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wave_directional_variance_spectral_density.json b/data_descriptors/standard_name/sea_surface_wave_directional_variance_spectral_density.json index 6835b4993..40db457e1 100644 --- a/data_descriptors/standard_name/sea_surface_wave_directional_variance_spectral_density.json +++ b/data_descriptors/standard_name/sea_surface_wave_directional_variance_spectral_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_directional_variance_spectral_density", + "id": "sea_surface_wave_directional_variance_spectral_density", "type": "standard_name", "name": "sea_surface_wave_directional_variance_spectral_density", "description": "Sea surface wave directional variance spectral density is the variance of the amplitude of the waves within given ranges of direction and wave frequency.", diff --git a/data_descriptors/standard_name/sea_surface_wave_energy_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wave_energy_at_variance_spectral_density_maximum.json index f44c8dd37..61d8dd69d 100644 --- a/data_descriptors/standard_name/sea_surface_wave_energy_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wave_energy_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_energy_at_variance_spectral_density_maximum", + "id": "sea_surface_wave_energy_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wave_energy_at_variance_spectral_density_maximum", "description": "The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density. The quantity with standard name sea_surface_wave_energy_at_variance_spectral_density_maximum, sometimes called peak wave energy, is the maximum value of the variance spectral density (max(S1)).", diff --git a/data_descriptors/standard_name/sea_surface_wave_energy_flux.json b/data_descriptors/standard_name/sea_surface_wave_energy_flux.json index 801090a32..cdf0a8cf7 100644 --- a/data_descriptors/standard_name/sea_surface_wave_energy_flux.json +++ b/data_descriptors/standard_name/sea_surface_wave_energy_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_energy_flux", + "id": "sea_surface_wave_energy_flux", "type": "standard_name", "name": "sea_surface_wave_energy_flux", "description": "Wave energy flux, or wave power, is the average rate of transfer of wave energy through a vertical plane of unit width perpendicular to the direction of wave propagation. It should be understood as omnidirectional, or as the sum of all wave power components regardless of direction. In deep water conditions, the wave energy flux can be obtained with the water density, the wave significant height and the energy period.", diff --git a/data_descriptors/standard_name/sea_surface_wave_frequency_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wave_frequency_at_variance_spectral_density_maximum.json index 510145f87..8137f858a 100644 --- a/data_descriptors/standard_name/sea_surface_wave_frequency_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wave_frequency_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_frequency_at_variance_spectral_density_maximum", + "id": "sea_surface_wave_frequency_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wave_frequency_at_variance_spectral_density_maximum", "description": "Frequency is the number of oscillations of a wave per unit time. The sea_surface_wave_frequency_at_variance_spectral_density_maximum is the frequency of the most energetic waves in the total wave spectrum at a specific location. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_wave_from_direction.json b/data_descriptors/standard_name/sea_surface_wave_from_direction.json index 504876ae6..dcec270d0 100644 --- a/data_descriptors/standard_name/sea_surface_wave_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_wave_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_from_direction", + "id": "sea_surface_wave_from_direction", "type": "standard_name", "name": "sea_surface_wave_from_direction", "description": "The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_wave_from_direction_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wave_from_direction_at_variance_spectral_density_maximum.json index 897c6a542..d90ab7325 100644 --- a/data_descriptors/standard_name/sea_surface_wave_from_direction_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wave_from_direction_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_from_direction_at_variance_spectral_density_maximum", + "id": "sea_surface_wave_from_direction_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wave_from_direction_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_wave_from_direction_at_variance_spectral_density_maximum is the direction from which the most energetic waves are coming. The spectral peak is the most energetic wave in the total wave spectrum. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_wave_maximum_crest_height.json b/data_descriptors/standard_name/sea_surface_wave_maximum_crest_height.json index 482882263..3881b0212 100644 --- a/data_descriptors/standard_name/sea_surface_wave_maximum_crest_height.json +++ b/data_descriptors/standard_name/sea_surface_wave_maximum_crest_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_maximum_crest_height", + "id": "sea_surface_wave_maximum_crest_height", "type": "standard_name", "name": "sea_surface_wave_maximum_crest_height", "description": "The crest is the highest point of a wave. Crest height is the vertical distance between the crest and the calm sea surface. Maximum crest height is the maximum value measured during the observation period.", diff --git a/data_descriptors/standard_name/sea_surface_wave_maximum_height.json b/data_descriptors/standard_name/sea_surface_wave_maximum_height.json index 9a4c38861..e149421e6 100644 --- a/data_descriptors/standard_name/sea_surface_wave_maximum_height.json +++ b/data_descriptors/standard_name/sea_surface_wave_maximum_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_maximum_height", + "id": "sea_surface_wave_maximum_height", "type": "standard_name", "name": "sea_surface_wave_maximum_height", "description": "Wave height is defined as the vertical distance from a wave trough to the following wave crest. The maximum wave height is the greatest trough to crest distance measured during the observation period.", diff --git a/data_descriptors/standard_name/sea_surface_wave_maximum_period.json b/data_descriptors/standard_name/sea_surface_wave_maximum_period.json index 4b2ab443e..40a9377e5 100644 --- a/data_descriptors/standard_name/sea_surface_wave_maximum_period.json +++ b/data_descriptors/standard_name/sea_surface_wave_maximum_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_maximum_period", + "id": "sea_surface_wave_maximum_period", "type": "standard_name", "name": "sea_surface_wave_maximum_period", "description": "The maximum wave period is the longest wave period measured during the observation period. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level.", diff --git a/data_descriptors/standard_name/sea_surface_wave_maximum_steepness.json b/data_descriptors/standard_name/sea_surface_wave_maximum_steepness.json index 16e43c8a2..ddd32e758 100644 --- a/data_descriptors/standard_name/sea_surface_wave_maximum_steepness.json +++ b/data_descriptors/standard_name/sea_surface_wave_maximum_steepness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_maximum_steepness", + "id": "sea_surface_wave_maximum_steepness", "type": "standard_name", "name": "sea_surface_wave_maximum_steepness", "description": "Wave steepness is defined as the ratio of the wave height divided by the wavelength. Maximum wave steepness is the maximum value measured during the observation period. Wave height is defined as the vertical distance from a wave trough to the following wave crest. The wavelength is the horizontal distance between repeated features on the waveform such as crests, troughs or upward passes through the mean level.", diff --git a/data_descriptors/standard_name/sea_surface_wave_maximum_trough_depth.json b/data_descriptors/standard_name/sea_surface_wave_maximum_trough_depth.json index 3d570420c..49818b847 100644 --- a/data_descriptors/standard_name/sea_surface_wave_maximum_trough_depth.json +++ b/data_descriptors/standard_name/sea_surface_wave_maximum_trough_depth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_maximum_trough_depth", + "id": "sea_surface_wave_maximum_trough_depth", "type": "standard_name", "name": "sea_surface_wave_maximum_trough_depth", "description": "The trough is the lowest point of a wave. Trough depth is the vertical distance between the trough and the calm sea surface. Maximum trough depth is the maximum value measured during the observation period.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_from_direction.json b/data_descriptors/standard_name/sea_surface_wave_mean_from_direction.json index 7e9a366a6..68d18c3fb 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_from_direction", + "id": "sea_surface_wave_mean_from_direction", "type": "standard_name", "name": "sea_surface_wave_mean_from_direction", "description": "The wave direction in each frequency band, calculated from the first-order components of the wave directional spectrum. The full directional wave spectrum is described as a Fourier series: S = a0/2 + a1cos(theta) + b1sin(theta) + a2cos(2theta) + b2sin(2theta). The Fourier coefficients a1, b1, a2, & b2 can be converted to polar coordinates as follows: R1 = (SQRT(a1a1+b1b1))/a0, R2 = (SQRT(a2a2+b2b2))/a0, ALPHA1 = 270.0-ARCTAN(b1,a1), ALPHA2 = 270.0-(0.5*ARCTAN(b2,a2)+{0 or 180, whichever minimizes the difference between ALPHA1 and ALPHA2}). ALPHA1 is the mean wave direction, which is determined from the first-order Fourier coefficients. This spectral parameter is a separate quantity from the bulk parameter (MWDIR), which has the standard name sea_surface_wave_from_direction_at_variance_spectral_density_maximum. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_height.json b/data_descriptors/standard_name/sea_surface_wave_mean_height.json index 45363a6ce..a34e0a1cf 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_height.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_height", + "id": "sea_surface_wave_mean_height", "type": "standard_name", "name": "sea_surface_wave_mean_height", "description": "Wave height is defined as the vertical distance from a wave trough to the following wave crest. The mean wave height is the mean trough to crest distance measured during the observation period.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_height_of_highest_tenth.json b/data_descriptors/standard_name/sea_surface_wave_mean_height_of_highest_tenth.json index 5043aca1c..d2691f63a 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_height_of_highest_tenth.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_height_of_highest_tenth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_height_of_highest_tenth", + "id": "sea_surface_wave_mean_height_of_highest_tenth", "type": "standard_name", "name": "sea_surface_wave_mean_height_of_highest_tenth", "description": "Wave height is defined as the vertical distance from a wave trough to the following wave crest. The height of the highest tenth is defined as the mean of the highest ten per cent of trough to crest distances measured during the observation period.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_period.json b/data_descriptors/standard_name/sea_surface_wave_mean_period.json index 41a3075d0..2eb3a80e1 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_period.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_period", + "id": "sea_surface_wave_mean_period", "type": "standard_name", "name": "sea_surface_wave_mean_period", "description": "A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. Wave mean period is the mean period measured over the observation duration.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json b/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json index 6edc854fa..7139a67f6 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment", + "id": "sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment", "type": "standard_name", "name": "sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment", "description": "The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density. Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The first wave period, T(m1) is calculated as the ratio M(0)/M(1).", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json b/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json index 2740a053b..f1d7485b5 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", + "id": "sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", "type": "standard_name", "name": "sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", "description": "The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density. Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The inverse wave period, T(m-1), is calculated as the ratio M(-1)/M(0).", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json b/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json index d19fe4e4a..7e5d037cd 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment", + "id": "sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment", "type": "standard_name", "name": "sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment", "description": "The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density. Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The second wave period, T(m2) is calculated as the square root of the ratio M(0)/M(2).", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_period_of_highest_tenth.json b/data_descriptors/standard_name/sea_surface_wave_mean_period_of_highest_tenth.json index 8f0957aa3..8a9739f78 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_period_of_highest_tenth.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_period_of_highest_tenth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_period_of_highest_tenth", + "id": "sea_surface_wave_mean_period_of_highest_tenth", "type": "standard_name", "name": "sea_surface_wave_mean_period_of_highest_tenth", "description": "Wave mean period is the mean period measured over the observation duration. The quantity with standard name sea_surface_wave_mean_period_of_highest_tenth is the mean period of the highest one-tenth of waves during the observation duration. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_square_slope.json b/data_descriptors/standard_name/sea_surface_wave_mean_square_slope.json index e8f789903..43d4f3aa8 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_square_slope.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_square_slope.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_square_slope", + "id": "sea_surface_wave_mean_square_slope", "type": "standard_name", "name": "sea_surface_wave_mean_square_slope", "description": "Wave slope describes an aspect of sea surface wave geometry related to sea surface roughness. Mean square slope describes a derivation over multiple waves within a sea-state, for example calculated from moments of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_square_x_slope.json b/data_descriptors/standard_name/sea_surface_wave_mean_square_x_slope.json index 560fad5d0..8a253beb2 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_square_x_slope.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_square_x_slope.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_square_x_slope", + "id": "sea_surface_wave_mean_square_x_slope", "type": "standard_name", "name": "sea_surface_wave_mean_square_x_slope", "description": "Wave slope describes an aspect of sea surface wave geometry related to sea surface roughness. Mean square slope describes a derivation over multiple waves within a sea-state, for example calculated from moments of the wave directional spectrum. The phrase \"x_slope\" indicates that slope values are derived from vector components along the grid x-axis.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_square_y_slope.json b/data_descriptors/standard_name/sea_surface_wave_mean_square_y_slope.json index f0ad1ae77..04696ea0b 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_square_y_slope.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_square_y_slope.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_square_y_slope", + "id": "sea_surface_wave_mean_square_y_slope", "type": "standard_name", "name": "sea_surface_wave_mean_square_y_slope", "description": "Wave slope describes an aspect of sea surface wave geometry related to sea surface roughness. Mean square slope describes a derivation over multiple waves within a sea-state, for example calculated from moments of the wave directional spectrum. The phrase \"y_slope\" indicates that slope values are derived from vector components along the grid y-axis.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment.json b/data_descriptors/standard_name/sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment.json index 98e1e8505..9c339923b 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment", + "id": "sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment", "type": "standard_name", "name": "sea_surface_wave_mean_wavelength_from_variance_spectral_density_inverse_wavenumber_moment", "description": "The wave directional spectrum can be written as a five dimensional function S(t,x,y,k,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), k is wavenumber and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density. Wavenumber is the number of oscillations of a wave per unit distance. Wavenumber moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 k^n dk), where k^n is k to the power of n. The inverse wave wavenumber, k(m-1), is calculated as the ratio M(-1)/M(0). The wavelength is the horizontal distance between repeated features on the waveform such as crests, troughs or upward passes through the mean level.", diff --git a/data_descriptors/standard_name/sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment.json b/data_descriptors/standard_name/sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment.json index ceb01af74..f4bd0bf0a 100644 --- a/data_descriptors/standard_name/sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment.json +++ b/data_descriptors/standard_name/sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment", + "id": "sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment", "type": "standard_name", "name": "sea_surface_wave_mean_wavenumber_from_variance_spectral_density_first_wavenumber_moment", "description": "The wave directional spectrum can be written as a five dimensional function S(t,x,y,k,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), k is wavenumber and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density. Wavenumber is the number of oscillations of a wave per unit distance. Wavenumber moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 k^n dk), where k^n is k to the power of n. The mean wavenumber, k(1), is calculated as the ratio M(1)/M(0).", diff --git a/data_descriptors/standard_name/sea_surface_wave_period_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wave_period_at_variance_spectral_density_maximum.json index 4a2440e7b..c940a2561 100644 --- a/data_descriptors/standard_name/sea_surface_wave_period_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wave_period_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_period_at_variance_spectral_density_maximum", + "id": "sea_surface_wave_period_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wave_period_at_variance_spectral_density_maximum", "description": "A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. The sea_surface_wave_period_at_variance_spectral_density_maximum, sometimes called peak wave period, is the period of the most energetic waves in the total wave spectrum at a specific location. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_wave_period_of_highest_wave.json b/data_descriptors/standard_name/sea_surface_wave_period_of_highest_wave.json index 343b5b1dd..a9d1e0dcb 100644 --- a/data_descriptors/standard_name/sea_surface_wave_period_of_highest_wave.json +++ b/data_descriptors/standard_name/sea_surface_wave_period_of_highest_wave.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_period_of_highest_wave", + "id": "sea_surface_wave_period_of_highest_wave", "type": "standard_name", "name": "sea_surface_wave_period_of_highest_wave", "description": "Wave period of the highest wave is the period determined from wave crests corresponding to the greatest vertical distance above mean level during the observation period. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level.", diff --git a/data_descriptors/standard_name/sea_surface_wave_principal_from_direction.json b/data_descriptors/standard_name/sea_surface_wave_principal_from_direction.json index c8f090234..ae9052245 100644 --- a/data_descriptors/standard_name/sea_surface_wave_principal_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_wave_principal_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_principal_from_direction", + "id": "sea_surface_wave_principal_from_direction", "type": "standard_name", "name": "sea_surface_wave_principal_from_direction", "description": "The wave direction in each frequency band, calculated from the second-order components of the wave directional spectrum. Since there is an ambiguity of 180 degrees in the calculation of Alpha2 (i.e. 90 degrees and 270 degrees result in equivalent spectra), the value closer to Alpha1 is selected. The full directional wave spectrum is described as a Fourier series: S = a0/2 + a1cos(theta) + b1sin(theta) + a2cos(2theta) + b2sin(2theta). The Fourier coefficients a1, b1, a2, & b2 can be converted to polar coordinates as follows: R1 = (SQRT(a1a1+b1b1))/a0, R2 = (SQRT(a2a2+b2b2))/a0, ALPHA1 = 270.0-ARCTAN(b1,a1), ALPHA2 = 270.0-(0.5*ARCTAN(b2,a2)+{0 or 180, whichever minimizes the difference between ALPHA1 and ALPHA2}). ALPHA2 is the principal wave direction, which is determined from the second-order Fourier coefficients. This spectral parameter is a separate quantity from the bulk parameter (MWDIR), which has the standard name sea_surface_wave_from_direction_at_variance_spectral_density_maximum. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_wave_significant_height.json index 3b49b8892..c4a82fc0c 100644 --- a/data_descriptors/standard_name/sea_surface_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_significant_height", + "id": "sea_surface_wave_significant_height", "type": "standard_name", "name": "sea_surface_wave_significant_height", "description": "Significant wave height is a statistic computed from wave measurements and corresponds to the average height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest.", diff --git a/data_descriptors/standard_name/sea_surface_wave_significant_period.json b/data_descriptors/standard_name/sea_surface_wave_significant_period.json index 1e1484c59..9e976eacf 100644 --- a/data_descriptors/standard_name/sea_surface_wave_significant_period.json +++ b/data_descriptors/standard_name/sea_surface_wave_significant_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_significant_period", + "id": "sea_surface_wave_significant_period", "type": "standard_name", "name": "sea_surface_wave_significant_period", "description": "Significant wave period is a statistic computed from wave measurements and corresponds to the mean wave period of the highest one third of the waves. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level.", diff --git a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_eastward_velocity.json b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_eastward_velocity.json index 8dd1f2fdc..a0b676a14 100644 --- a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_eastward_velocity.json +++ b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_eastward_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_stokes_drift_eastward_velocity", + "id": "sea_surface_wave_stokes_drift_eastward_velocity", "type": "standard_name", "name": "sea_surface_wave_stokes_drift_eastward_velocity", "description": "A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The Stokes drift velocity is the average velocity when following a specific fluid parcel as it travels with the fluid flow. For instance, a particle floating at the free surface of water waves, experiences a net Stokes drift velocity in the direction of wave propagation.", diff --git a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_northward_velocity.json b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_northward_velocity.json index 110d5f519..f048f0869 100644 --- a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_northward_velocity.json +++ b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_northward_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_stokes_drift_northward_velocity", + "id": "sea_surface_wave_stokes_drift_northward_velocity", "type": "standard_name", "name": "sea_surface_wave_stokes_drift_northward_velocity", "description": "A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). The Stokes drift velocity is the average velocity when following a specific fluid parcel as it travels with the fluid flow. For instance, a particle floating at the free surface of water waves, experiences a net Stokes drift velocity in the direction of wave propagation.", diff --git a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_speed.json b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_speed.json index 1f2dbf6c9..ba9ddd8b1 100644 --- a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_speed.json +++ b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_stokes_drift_speed", + "id": "sea_surface_wave_stokes_drift_speed", "type": "standard_name", "name": "sea_surface_wave_stokes_drift_speed", "description": "The Stokes drift velocity is the average velocity when following a specific fluid parcel as it travels with the fluid flow. For instance, a particle floating at the free surface of water waves, experiences a net Stokes drift velocity in the direction of wave propagation. Speed is the magnitude of velocity.", diff --git a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_to_direction.json b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_to_direction.json index 92d37b1ee..8a1627947 100644 --- a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_to_direction.json +++ b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_to_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_stokes_drift_to_direction", + "id": "sea_surface_wave_stokes_drift_to_direction", "type": "standard_name", "name": "sea_surface_wave_stokes_drift_to_direction", "description": "The Stokes drift velocity is the average velocity when following a specific fluid parcel as it travels with the fluid flow. For instance, a particle floating at the free surface of water waves, experiences a net Stokes drift velocity in the direction of wave propagation. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_x_velocity.json b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_x_velocity.json index b2013c7c4..94f9dd07e 100644 --- a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_x_velocity.json +++ b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_stokes_drift_x_velocity", + "id": "sea_surface_wave_stokes_drift_x_velocity", "type": "standard_name", "name": "sea_surface_wave_stokes_drift_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. The Stokes drift velocity is the average velocity when following a specific fluid parcel as it travels with the fluid flow. For instance, a particle floating at the free surface of water waves, experiences a net Stokes drift velocity in the direction of wave propagation.", diff --git a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_y_velocity.json b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_y_velocity.json index 7203e5524..b78bbb8e9 100644 --- a/data_descriptors/standard_name/sea_surface_wave_stokes_drift_y_velocity.json +++ b/data_descriptors/standard_name/sea_surface_wave_stokes_drift_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_stokes_drift_y_velocity", + "id": "sea_surface_wave_stokes_drift_y_velocity", "type": "standard_name", "name": "sea_surface_wave_stokes_drift_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid x-axis, positive with increasing y. The Stokes drift velocity is the average velocity when following a specific fluid parcel as it travels with the fluid flow. For instance, a particle floating at the free surface of water waves, experiences a net Stokes drift velocity in the direction of wave propagation.", diff --git a/data_descriptors/standard_name/sea_surface_wave_to_direction.json b/data_descriptors/standard_name/sea_surface_wave_to_direction.json index cf4316eae..183c2b88a 100644 --- a/data_descriptors/standard_name/sea_surface_wave_to_direction.json +++ b/data_descriptors/standard_name/sea_surface_wave_to_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_to_direction", + "id": "sea_surface_wave_to_direction", "type": "standard_name", "name": "sea_surface_wave_to_direction", "description": "The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_wave_variance_spectral_density.json b/data_descriptors/standard_name/sea_surface_wave_variance_spectral_density.json index 00a111432..25b25cc77 100644 --- a/data_descriptors/standard_name/sea_surface_wave_variance_spectral_density.json +++ b/data_descriptors/standard_name/sea_surface_wave_variance_spectral_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_variance_spectral_density", + "id": "sea_surface_wave_variance_spectral_density", "type": "standard_name", "name": "sea_surface_wave_variance_spectral_density", "description": "Sea surface wave variance spectral density is the variance of wave amplitude within a range of wave frequency.", diff --git a/data_descriptors/standard_name/sea_surface_wave_xx_radiation_stress.json b/data_descriptors/standard_name/sea_surface_wave_xx_radiation_stress.json index 0890966e9..8d89d1eb5 100644 --- a/data_descriptors/standard_name/sea_surface_wave_xx_radiation_stress.json +++ b/data_descriptors/standard_name/sea_surface_wave_xx_radiation_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_xx_radiation_stress", + "id": "sea_surface_wave_xx_radiation_stress", "type": "standard_name", "name": "sea_surface_wave_xx_radiation_stress", "description": "\"Sea surface wave radiation stress\" describes the excess momentum flux caused by sea surface waves. Radiation stresses behave as a second-order tensor. \"xx\" indicates the component of the tensor along the grid x_ axis.", diff --git a/data_descriptors/standard_name/sea_surface_wave_xy_radiation_stress.json b/data_descriptors/standard_name/sea_surface_wave_xy_radiation_stress.json index 2e9c65a2a..995b0fb0e 100644 --- a/data_descriptors/standard_name/sea_surface_wave_xy_radiation_stress.json +++ b/data_descriptors/standard_name/sea_surface_wave_xy_radiation_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_xy_radiation_stress", + "id": "sea_surface_wave_xy_radiation_stress", "type": "standard_name", "name": "sea_surface_wave_xy_radiation_stress", "description": "\"Sea surface wave radiation stress\" describes the excess momentum flux caused by sea surface waves. Radiation stresses behave as a second-order tensor. \"xy\" indicates the lateral contributions to x_ and y_ components of the tensor.", diff --git a/data_descriptors/standard_name/sea_surface_wave_yy_radiation_stress.json b/data_descriptors/standard_name/sea_surface_wave_yy_radiation_stress.json index 16087f542..d049bf737 100644 --- a/data_descriptors/standard_name/sea_surface_wave_yy_radiation_stress.json +++ b/data_descriptors/standard_name/sea_surface_wave_yy_radiation_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wave_yy_radiation_stress", + "id": "sea_surface_wave_yy_radiation_stress", "type": "standard_name", "name": "sea_surface_wave_yy_radiation_stress", "description": "\"Sea surface wave radiation stress\" describes the excess momentum flux caused by sea surface waves. Radiation stresses behave as a second-order tensor. \"yy\" indicates the component of the tensor along the grid y_ axis.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_directional_spread.json b/data_descriptors/standard_name/sea_surface_wind_wave_directional_spread.json index f8f5d6ac5..9eb81e1a5 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_directional_spread.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_directional_spread.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_directional_spread", + "id": "sea_surface_wind_wave_directional_spread", "type": "standard_name", "name": "sea_surface_wind_wave_directional_spread", "description": "The quantity with standard name sea_surface_wind_wave_directional_spread is the directional width of the wind wave component of a sea. Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. Directional spread is the (one-sided) directional width within a given sub-domain of the wave directional spectrum, S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. For a given mean wave (beam) direction the quantity approximates half the root mean square width about the beam axis, as derived either directly from circular moments or via the Fourier components of the wave directional spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_energy_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wind_wave_energy_at_variance_spectral_density_maximum.json index 7448a7f67..46832d837 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_energy_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_energy_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_energy_at_variance_spectral_density_maximum", + "id": "sea_surface_wind_wave_energy_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wind_wave_energy_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_wind_wave_energy_at_variance_spectral_density_maximum is the energy of the most energetic waves within the wind wave component of a sea. Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. The phrase \"wave_energy_at_variance_spectral_density_maximum\", sometimes called peak wave energy, describes the maximum value of the wave_variance_spectral_density within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_from_direction.json b/data_descriptors/standard_name/sea_surface_wind_wave_from_direction.json index af434c667..2f4440b8b 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_from_direction.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_from_direction", + "id": "sea_surface_wind_wave_from_direction", "type": "standard_name", "name": "sea_surface_wind_wave_from_direction", "description": "Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum.json index e361732ef..2dc2a8ef9 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum", + "id": "sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_wind_wave_from_direction_at_variance_spectral_density_maximum is the direction from which the most energetic waves are coming in the wind wave component of a sea. Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. The spectral peak is the most energetic wave in the wave spectrum partition. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S has the standard name sea_surface_wave_directional_variance_spectral_density. S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period.json b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period.json index 1035ad568..3b705cb7a 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_mean_period", + "id": "sea_surface_wind_wave_mean_period", "type": "standard_name", "name": "sea_surface_wind_wave_mean_period", "description": "A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. Wave mean period is the mean period measured over the observation duration. Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json index 89decd858..e8c764d61 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment", + "id": "sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment", "type": "standard_name", "name": "sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment", "description": "The wind wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S can be integrated over direction to give S1= integral(S dtheta) . Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The first wave period, T(m1) is calculated as the ratio M(0)/M(1).", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json index b4377c5d0..84d0d4056 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", + "id": "sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", "type": "standard_name", "name": "sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment", "description": "The wind wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S can be integrated over direction to give S1= integral(S dtheta). Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The inverse wave period, T(m-1), is calculated as the ratio M(-1)/M(0).", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json index 1a654e1e6..dc94930c8 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment", + "id": "sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment", "type": "standard_name", "name": "sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment", "description": "The wind wave directional spectrum can be written as a five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction. S can be integrated over direction, thus S1= integral(S dtheta). Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n. The second wave period, T(m2), is calculated as the square root of the ratio M(0)/M(2).", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_period.json b/data_descriptors/standard_name/sea_surface_wind_wave_period.json index 713a22b03..10e4441e4 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_period.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_period.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_period", + "id": "sea_surface_wind_wave_period", "type": "standard_name", "name": "sea_surface_wind_wave_period", "description": "A period is an interval of time, or the time-period of an oscillation. Wind waves are waves on the ocean surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_period_at_variance_spectral_density_maximum.json b/data_descriptors/standard_name/sea_surface_wind_wave_period_at_variance_spectral_density_maximum.json index 872953c88..37defcf61 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_period_at_variance_spectral_density_maximum.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_period_at_variance_spectral_density_maximum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_period_at_variance_spectral_density_maximum", + "id": "sea_surface_wind_wave_period_at_variance_spectral_density_maximum", "type": "standard_name", "name": "sea_surface_wind_wave_period_at_variance_spectral_density_maximum", "description": "The quantity with standard name sea_surface_wind_wave_period_at_variance_spectral_density_maximum is the period of the most energetic waves within the wind wave component of a sea. Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. A period is an interval of time, or the time-period of an oscillation. Wave period is the interval of time between repeated features on the waveform such as crests, troughs or upward passes through the mean level. The phrase \"wave_period_at_variance_spectral_density_maximum\", sometimes called peak wave period, describes the period of the most energetic waves within a given sub-domain of the wave spectrum.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_significant_height.json b/data_descriptors/standard_name/sea_surface_wind_wave_significant_height.json index d9a8dfad8..f2f4f6c48 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_significant_height.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_significant_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_significant_height", + "id": "sea_surface_wind_wave_significant_height", "type": "standard_name", "name": "sea_surface_wind_wave_significant_height", "description": "Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. Significant wave height is a statistic computed from wave measurements and corresponds to the average height of the highest one third of the waves, where the height is defined as the vertical distance from a wave trough to the following wave crest.", diff --git a/data_descriptors/standard_name/sea_surface_wind_wave_to_direction.json b/data_descriptors/standard_name/sea_surface_wind_wave_to_direction.json index e52f9aea8..733c4338f 100644 --- a/data_descriptors/standard_name/sea_surface_wind_wave_to_direction.json +++ b/data_descriptors/standard_name/sea_surface_wind_wave_to_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_surface_wind_wave_to_direction", + "id": "sea_surface_wind_wave_to_direction", "type": "standard_name", "name": "sea_surface_wind_wave_to_direction", "description": "Wind waves are waves on the ocean surface and are the high frequency portion of a bimodal wave frequency spectrum. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_water_absolute_salinity.json b/data_descriptors/standard_name/sea_water_absolute_salinity.json index 753fc3084..59e264faf 100644 --- a/data_descriptors/standard_name/sea_water_absolute_salinity.json +++ b/data_descriptors/standard_name/sea_water_absolute_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_absolute_salinity", + "id": "sea_water_absolute_salinity", "type": "standard_name", "name": "sea_water_absolute_salinity", "description": "Absolute Salinity, S_A, is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the Intergovernmental Oceanographic Commission (IOC). It is the mass fraction of dissolved material in sea water. Absolute Salinity incorporates the spatial variations in the composition of sea water. This type of Absolute Salinity is also called \"Density Salinity\". TEOS-10 estimates Absolute Salinity as the salinity variable that, when used with the TEOS-10 expression for density, yields the correct density of a sea water sample even when the sample is not of Reference Composition. In practice, Absolute Salinity is often calculated from Practical Salinity using a spatial lookup table of pre-defined values of the Absolute Salinity Anomaly. It is recommended that the version of (TEOS-10) software and the associated Absolute Salinity Anomaly climatology be specified within metadata by attaching a comment attribute to the data variable. Reference: www.teos-10.org; Millero et al., 2008 doi: 10.1016/j.dsr.2007.10.001. There are also standard names for the precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 onwards), sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/sea_water_added_conservative_temperature.json b/data_descriptors/standard_name/sea_water_added_conservative_temperature.json index 1b7d9b6d4..4fe6c16f2 100644 --- a/data_descriptors/standard_name/sea_water_added_conservative_temperature.json +++ b/data_descriptors/standard_name/sea_water_added_conservative_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_added_conservative_temperature", + "id": "sea_water_added_conservative_temperature", "type": "standard_name", "name": "sea_water_added_conservative_temperature", "description": "The quantity with standard name sea_water_added_conservative_temperature is a passive tracer in an ocean model whose surface flux does not come from the atmosphere but is imposed externally upon the simulated climate system. The surface flux is expressed as a heat flux and converted to a passive tracer increment as if it were a heat flux being added to conservative temperature. The passive tracer is transported within the ocean as if it were conservative temperature. The passive tracer is zero in the control climate of the model. The passive tracer records added heat, as described for the CMIP6 FAFMIP experiment (doi:10.5194/gmd-9-3993-2016), following earlier ideas. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_added_potential_temperature.json b/data_descriptors/standard_name/sea_water_added_potential_temperature.json index 3e3513e3d..1767759f7 100644 --- a/data_descriptors/standard_name/sea_water_added_potential_temperature.json +++ b/data_descriptors/standard_name/sea_water_added_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_added_potential_temperature", + "id": "sea_water_added_potential_temperature", "type": "standard_name", "name": "sea_water_added_potential_temperature", "description": "The quantity with standard name sea_water_added_potential_temperature is a passive tracer in an ocean model whose surface flux does not come from the atmosphere but is imposed externally upon the simulated climate system. The surface flux is expressed as a heat flux and converted to a passive tracer increment as if it were a heat flux being added to potential temperature. The passive tracer is transported within the ocean as if it were potential temperature. The passive tracer is zero in the control climate of the model. The passive tracer records added heat, as described for the CMIP6 FAFMIP experiment (doi:10.5194/gmd-9-3993-2016), following earlier ideas. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_age_since_surface_contact.json b/data_descriptors/standard_name/sea_water_age_since_surface_contact.json index 6b024cf8f..972715c43 100644 --- a/data_descriptors/standard_name/sea_water_age_since_surface_contact.json +++ b/data_descriptors/standard_name/sea_water_age_since_surface_contact.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_age_since_surface_contact", + "id": "sea_water_age_since_surface_contact", "type": "standard_name", "name": "sea_water_age_since_surface_contact", "description": "\"Sea water age since surface contact\" means the length of time elapsed since the sea water in a grid cell was last in the surface level of an ocean model.", diff --git a/data_descriptors/standard_name/sea_water_alkalinity_expressed_as_mole_equivalent.json b/data_descriptors/standard_name/sea_water_alkalinity_expressed_as_mole_equivalent.json index 1c2e3b8e0..07d22c5b9 100644 --- a/data_descriptors/standard_name/sea_water_alkalinity_expressed_as_mole_equivalent.json +++ b/data_descriptors/standard_name/sea_water_alkalinity_expressed_as_mole_equivalent.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_alkalinity_expressed_as_mole_equivalent", + "id": "sea_water_alkalinity_expressed_as_mole_equivalent", "type": "standard_name", "name": "sea_water_alkalinity_expressed_as_mole_equivalent", "description": "'sea_water_alkalinity_expressed_as_mole_equivalent' is the total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components).", diff --git a/data_descriptors/standard_name/sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent.json b/data_descriptors/standard_name/sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent.json index 0b5bd9be3..33306926e 100644 --- a/data_descriptors/standard_name/sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent.json +++ b/data_descriptors/standard_name/sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent", + "id": "sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent", "type": "standard_name", "name": "sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent", "description": "sea_water_alkalinity_expressed_as_mole_equivalent is the total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components). In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings.", diff --git a/data_descriptors/standard_name/sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent.json b/data_descriptors/standard_name/sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent.json index 8d65fe0fd..9b41ef07f 100644 --- a/data_descriptors/standard_name/sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent.json +++ b/data_descriptors/standard_name/sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent", + "id": "sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent", "type": "standard_name", "name": "sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent", "description": "The standard name sea_water_alkalinity_per_unit_mass_expressed_as_mole_equivalent is the total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components) expressed as the number of moles of alkalinity per unit mass of seawater. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The equivalent term in the NERC P01 Parameter Usage Vocabulary may be found at http://vocab.nerc.ac.uk/collection/P01/current/MDMAP014/1/.", diff --git a/data_descriptors/standard_name/sea_water_conservative_temperature.json b/data_descriptors/standard_name/sea_water_conservative_temperature.json index ca37e1a06..64a206cbe 100644 --- a/data_descriptors/standard_name/sea_water_conservative_temperature.json +++ b/data_descriptors/standard_name/sea_water_conservative_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_conservative_temperature", + "id": "sea_water_conservative_temperature", "type": "standard_name", "name": "sea_water_conservative_temperature", "description": "Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_cox_salinity.json b/data_descriptors/standard_name/sea_water_cox_salinity.json index 37710bd18..e7bb4df12 100644 --- a/data_descriptors/standard_name/sea_water_cox_salinity.json +++ b/data_descriptors/standard_name/sea_water_cox_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_cox_salinity", + "id": "sea_water_cox_salinity", "type": "standard_name", "name": "sea_water_cox_salinity", "description": "Cox Salinity, S_C, is defined unitless as a mass fraction per mil (0/00) or \"parts per thousand\". S_C was the standard salinity measure from 1967 until Practical Salinity, S_P, was established with PSS-78 (1978). Chlorinity, Cl, is calculated from the conductivity of a sea water sample and since the work of the Joint Panel for Oceanographic Tables and Standards (JPOTS; 1966) is converted into Cox Salinity using S_C = 1.80655Cl. This type of salinity was called simply \"salinity\" from 1967 to 1978. Cox Salinity was replaced by Practical Salinity in 1978. Cox Salinity is converted to Practical Salinity following S_P = S_C, however the accuracy of this is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of the Practical Salinity Scale 1978 (PSS-78). Reference: Cox et al., 1967 doi: 10.1016/0011-7471(67)90006-X; Lyman, 1969 doi: 10.4319/lo.1969.14.6.0928; Wooster et al., 1969 doi: 10.4319/lo.1969.14.3.0437. There are standard names for the precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_practical_salinity, S_P, sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_* and sea_water_reference_salinity. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/sea_water_density.json b/data_descriptors/standard_name/sea_water_density.json index ec1213b37..75ba3428f 100644 --- a/data_descriptors/standard_name/sea_water_density.json +++ b/data_descriptors/standard_name/sea_water_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_density", + "id": "sea_water_density", "type": "standard_name", "name": "sea_water_density", "description": "Sea water density is the in-situ density (not the potential density). If 1000 kg m-3 is subtracted, the standard name sea_water_sigma_t should be chosen instead.", diff --git a/data_descriptors/standard_name/sea_water_electrical_conductivity.json b/data_descriptors/standard_name/sea_water_electrical_conductivity.json index be5ede39f..832ebb542 100644 --- a/data_descriptors/standard_name/sea_water_electrical_conductivity.json +++ b/data_descriptors/standard_name/sea_water_electrical_conductivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_electrical_conductivity", + "id": "sea_water_electrical_conductivity", "type": "standard_name", "name": "sea_water_electrical_conductivity", "description": null, diff --git a/data_descriptors/standard_name/sea_water_electrical_conductivity_at_reference_temperature.json b/data_descriptors/standard_name/sea_water_electrical_conductivity_at_reference_temperature.json index ca1128716..1ebfc6b09 100644 --- a/data_descriptors/standard_name/sea_water_electrical_conductivity_at_reference_temperature.json +++ b/data_descriptors/standard_name/sea_water_electrical_conductivity_at_reference_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_electrical_conductivity_at_reference_temperature", + "id": "sea_water_electrical_conductivity_at_reference_temperature", "type": "standard_name", "name": "sea_water_electrical_conductivity_at_reference_temperature", "description": "The electrical conductivity of sea water in a sample measured at a defined reference temperature. The reference temperature should be recorded in a scalar coordinate variable, or a coordinate variable with a single dimension of size one, and the standard name of temperature_of_analysis_of_sea_water. This quantity is sometimes called 'specific conductivity' when the reference temperature 25 degrees Celsius.", diff --git a/data_descriptors/standard_name/sea_water_knudsen_salinity.json b/data_descriptors/standard_name/sea_water_knudsen_salinity.json index 26865d8e5..a7260885a 100644 --- a/data_descriptors/standard_name/sea_water_knudsen_salinity.json +++ b/data_descriptors/standard_name/sea_water_knudsen_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_knudsen_salinity", + "id": "sea_water_knudsen_salinity", "type": "standard_name", "name": "sea_water_knudsen_salinity", "description": "Knudsen Salinity, S_K, is defined unitless as a mass fraction per mil (0/00) or \"parts per thousand\", and was calculated from the titration of inorganic salts from a sample of sea water after a commission to study the problem of determining salinity and density was initiated by the International Council for the Exploration of the Sea (ICES) in 1899. S_K was the standard salinity measure until S_C (Cox Salinity) was established in 1967. Since the work of Knudsen (1901), chlorinity is converted into Knudsen Salinity using S_K = 0.030 + 1.805 Cl. This type of salinity was called simply \"salinity\" from 1901 to 1966. From the 1960s on, electrical conductivity began to be used to estimate the Knudsen Salinity, rather than chemical titration. Knudsen Salinity was replaced by Cox Salinity in 1967 which was in turn replaced by Practical Salinity, S_P, in 1978. Conversion of Knudsen Salinity to Practical Salinity follows S_P = (S_K - 0.03) * (1.80655 / 1.805). Reference: Knudsen, 1901; Thomas et al., 1934 doi: 10.1093/icesjms/9.1.28; Lyman, 1969 doi: 10.4319/lo.1969.14.6.0928; Wooster et al., 1969 doi: 10.4319/lo.1969.14.3.0437; Lewis, 1980 doi: 10.1109/JOE.1980.1145448; Millero et al., 2008 doi: 10.1016/j.dsr.2007.10.001. There are standard names for the precisely defined salinity quantities sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P, sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_* and sea_water_reference_salinity. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/sea_water_mass.json b/data_descriptors/standard_name/sea_water_mass.json index 09240a9fb..2549a5302 100644 --- a/data_descriptors/standard_name/sea_water_mass.json +++ b/data_descriptors/standard_name/sea_water_mass.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_mass", + "id": "sea_water_mass", "type": "standard_name", "name": "sea_water_mass", "description": "The quantity with standard name \"sea_water_mass\" is the total mass of liquid seawater in the global oceans, including enclosed seas.", diff --git a/data_descriptors/standard_name/sea_water_mass_per_unit_area.json b/data_descriptors/standard_name/sea_water_mass_per_unit_area.json index 4c0128dd5..68563a754 100644 --- a/data_descriptors/standard_name/sea_water_mass_per_unit_area.json +++ b/data_descriptors/standard_name/sea_water_mass_per_unit_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_mass_per_unit_area", + "id": "sea_water_mass_per_unit_area", "type": "standard_name", "name": "sea_water_mass_per_unit_area", "description": "Sea_water_mass_per_unit_area is the mass per unit area of the sea water contained within each grid cell.", diff --git a/data_descriptors/standard_name/sea_water_mass_per_unit_area_expressed_as_thickness.json b/data_descriptors/standard_name/sea_water_mass_per_unit_area_expressed_as_thickness.json index 7e58afbac..d04798d83 100644 --- a/data_descriptors/standard_name/sea_water_mass_per_unit_area_expressed_as_thickness.json +++ b/data_descriptors/standard_name/sea_water_mass_per_unit_area_expressed_as_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_mass_per_unit_area_expressed_as_thickness", + "id": "sea_water_mass_per_unit_area_expressed_as_thickness", "type": "standard_name", "name": "sea_water_mass_per_unit_area_expressed_as_thickness", "description": "\"Thickness\" means the vertical extent of a layer. The quantity with standard name sea_water_mass_per_unit_area_expressed_as_thickness is the thickness of the water column from sea floor to surface, minus any contribution to column thickness from steric changes. The sea water density used to convert mass to thickness is assumed to be the density of water of standard temperature zero degrees Celsius and practical salinity S=35.0 unless an auxiliary scalar coordinate variable with standard name sea_water_density is used to specify an alternative value. The sum of the quantities with standard names sea_water_mass_per_unit_area_expressed_as_thickness and steric_change_in_sea_surface_height is the total thickness of the sea water column. Sea_water_mass_per_unit_area is the mass per unit area of the sea water contained within each grid cell. The extent of an individual grid cell is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\".", diff --git a/data_descriptors/standard_name/sea_water_neutral_density.json b/data_descriptors/standard_name/sea_water_neutral_density.json index 6ba01826e..6cac0919e 100644 --- a/data_descriptors/standard_name/sea_water_neutral_density.json +++ b/data_descriptors/standard_name/sea_water_neutral_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_neutral_density", + "id": "sea_water_neutral_density", "type": "standard_name", "name": "sea_water_neutral_density", "description": "\"Neutral density\" is a variable designed so that a surface of constant neutral density everywhere has a local slope that is close to the local slope of the neutral tangent plane. At the sea surface in the equatorial Pacific neutral density is very close to the potential density anomaly. At other locations, this is not the case. For example, along a neutral density surface there is a difference of up to 0.14 kg/m^3 in the potential density anomaly at the outcrops in the Southern and Northern hemispheres. Refer to Jackett & McDougall (1997; Journal of Physical Oceanography, Vol 27, doi: 10.1175/1520-0485(1997)027<0237:ANDVFT>2.0.CO;2) for more information.", diff --git a/data_descriptors/standard_name/sea_water_ph_abiotic_analogue_reported_on_total_scale.json b/data_descriptors/standard_name/sea_water_ph_abiotic_analogue_reported_on_total_scale.json index 03c4cffdc..ba99b5095 100644 --- a/data_descriptors/standard_name/sea_water_ph_abiotic_analogue_reported_on_total_scale.json +++ b/data_descriptors/standard_name/sea_water_ph_abiotic_analogue_reported_on_total_scale.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_ph_abiotic_analogue_reported_on_total_scale", + "id": "sea_water_ph_abiotic_analogue_reported_on_total_scale", "type": "standard_name", "name": "sea_water_ph_abiotic_analogue_reported_on_total_scale", "description": "sea_water_pH_reported_on_total_scale is the measure of acidity of sea water, defined as the negative logarithm of the concentration of dissolved hydrogen ions plus bisulfate ions in a sea water medium; it can be measured or calculated; when measured the scale is defined according to a series of buffers prepared in artificial seawater containing bisulfate. The quantity may be written as pH(total) = -log([H+](free) + [HSO4-]). In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored.", diff --git a/data_descriptors/standard_name/sea_water_ph_natural_analogue_reported_on_total_scale.json b/data_descriptors/standard_name/sea_water_ph_natural_analogue_reported_on_total_scale.json index be0143ec2..3e11e7aa3 100644 --- a/data_descriptors/standard_name/sea_water_ph_natural_analogue_reported_on_total_scale.json +++ b/data_descriptors/standard_name/sea_water_ph_natural_analogue_reported_on_total_scale.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_ph_natural_analogue_reported_on_total_scale", + "id": "sea_water_ph_natural_analogue_reported_on_total_scale", "type": "standard_name", "name": "sea_water_ph_natural_analogue_reported_on_total_scale", "description": "sea_water_pH_reported_on_total_scale is the measure of acidity of sea water, defined as the negative logarithm of the concentration of dissolved hydrogen ions plus bisulfate ions in a sea water medium; it can be measured or calculated; when measured the scale is defined according to a series of buffers prepared in artificial seawater containing bisulfate. The quantity may be written as pH(total) = -log([H+](free) + [HSO4-]). In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings.", diff --git a/data_descriptors/standard_name/sea_water_ph_reported_on_total_scale.json b/data_descriptors/standard_name/sea_water_ph_reported_on_total_scale.json index a548784cc..4c36e654d 100644 --- a/data_descriptors/standard_name/sea_water_ph_reported_on_total_scale.json +++ b/data_descriptors/standard_name/sea_water_ph_reported_on_total_scale.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_ph_reported_on_total_scale", + "id": "sea_water_ph_reported_on_total_scale", "type": "standard_name", "name": "sea_water_ph_reported_on_total_scale", "description": "'sea_water_pH_reported_on_total_scale' is the measure of acidity of seawater, defined as the negative logarithm of the concentration of dissolved hydrogen ions plus bisulfate ions in a sea water medium; it can be measured or calculated; when measured the scale is defined according to a series of buffers prepared in artificial seawater containing bisulfate. The quantity may be written as pH(total) = -log([H+](free) + [HSO4-]).", diff --git a/data_descriptors/standard_name/sea_water_potential_density.json b/data_descriptors/standard_name/sea_water_potential_density.json index 9628fbcda..6a30339e1 100644 --- a/data_descriptors/standard_name/sea_water_potential_density.json +++ b/data_descriptors/standard_name/sea_water_potential_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_potential_density", + "id": "sea_water_potential_density", "type": "standard_name", "name": "sea_water_potential_density", "description": "Sea water potential density is the density a parcel of sea water would have if moved adiabatically to a reference pressure, by default assumed to be sea level pressure. To specify the reference pressure to which the quantity applies, provide a scalar coordinate variable with standard name reference_pressure. The density of a substance is its mass per unit volume. For sea water potential density, if 1000 kg m-3 is subtracted, the standard name sea_water_sigma_theta should be chosen instead.", diff --git a/data_descriptors/standard_name/sea_water_potential_temperature.json b/data_descriptors/standard_name/sea_water_potential_temperature.json index 363bf3ba9..ce8eac5d6 100644 --- a/data_descriptors/standard_name/sea_water_potential_temperature.json +++ b/data_descriptors/standard_name/sea_water_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_potential_temperature", + "id": "sea_water_potential_temperature", "type": "standard_name", "name": "sea_water_potential_temperature", "description": "Sea water potential temperature is the temperature a parcel of sea water would have if moved adiabatically to sea level pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_potential_temperature_at_sea_floor.json b/data_descriptors/standard_name/sea_water_potential_temperature_at_sea_floor.json index ec17b50bf..cbbd32197 100644 --- a/data_descriptors/standard_name/sea_water_potential_temperature_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_potential_temperature_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_potential_temperature_at_sea_floor", + "id": "sea_water_potential_temperature_at_sea_floor", "type": "standard_name", "name": "sea_water_potential_temperature_at_sea_floor", "description": "Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The potential temperature at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_potential_temperature_expressed_as_heat_content.json b/data_descriptors/standard_name/sea_water_potential_temperature_expressed_as_heat_content.json index 8364814ce..e12912897 100644 --- a/data_descriptors/standard_name/sea_water_potential_temperature_expressed_as_heat_content.json +++ b/data_descriptors/standard_name/sea_water_potential_temperature_expressed_as_heat_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_potential_temperature_expressed_as_heat_content", + "id": "sea_water_potential_temperature_expressed_as_heat_content", "type": "standard_name", "name": "sea_water_potential_temperature_expressed_as_heat_content", "description": "The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", diff --git a/data_descriptors/standard_name/sea_water_practical_salinity.json b/data_descriptors/standard_name/sea_water_practical_salinity.json index 38bac7e41..925cdf30c 100644 --- a/data_descriptors/standard_name/sea_water_practical_salinity.json +++ b/data_descriptors/standard_name/sea_water_practical_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_practical_salinity", + "id": "sea_water_practical_salinity", "type": "standard_name", "name": "sea_water_practical_salinity", "description": "Practical Salinity, S_P, is a determination of the salinity of sea water, based on its electrical conductance. The measured conductance, corrected for temperature and pressure, is compared to the conductance of a standard potassium chloride solution, producing a value on the Practical Salinity Scale of 1978 (PSS-78). This name should not be used to describe salinity observations made before 1978, or ones not based on conductance measurements. Conversion of Practical Salinity to other precisely defined salinity measures should use the appropriate formulas specified by TEOS-10. Other standard names for precisely defined salinity quantities are sea_water_absolute_salinity (S_A); sea_water_preformed_salinity (S_*), sea_water_reference_salinity (S_R); sea_water_cox_salinity (S_C), used for salinity observations between 1967 and 1977; and sea_water_knudsen_salinity (S_K), used for salinity observations between 1901 and 1966. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity. Reference: www.teos-10.org; Lewis, 1980 doi:10.1109/JOE.1980.1145448.", diff --git a/data_descriptors/standard_name/sea_water_practical_salinity_at_sea_floor.json b/data_descriptors/standard_name/sea_water_practical_salinity_at_sea_floor.json index 4fba68138..56e8ddaba 100644 --- a/data_descriptors/standard_name/sea_water_practical_salinity_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_practical_salinity_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_practical_salinity_at_sea_floor", + "id": "sea_water_practical_salinity_at_sea_floor", "type": "standard_name", "name": "sea_water_practical_salinity_at_sea_floor", "description": "The practical salinity at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements. Practical Salinity, S_P, is a determination of the salinity of sea water, based on its electrical conductance. The measured conductance, corrected for temperature and pressure, is compared to the conductance of a standard potassium chloride solution, producing a value on the Practical Salinity Scale of 1978 (PSS-78). This name should not be used to describe salinity observations made before 1978, or ones not based on conductance measurements. Conversion of Practical Salinity to other precisely defined salinity measures should use the appropriate formulas specified by TEOS-10. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity_at_sea_floor. Reference: www.teos-10.org; Lewis, 1980 doi:10.1109/JOE.1980.1145448.", diff --git a/data_descriptors/standard_name/sea_water_preformed_alkalinity_expressed_as_mole_equivalent.json b/data_descriptors/standard_name/sea_water_preformed_alkalinity_expressed_as_mole_equivalent.json index 49c947a97..5f2c07f0a 100644 --- a/data_descriptors/standard_name/sea_water_preformed_alkalinity_expressed_as_mole_equivalent.json +++ b/data_descriptors/standard_name/sea_water_preformed_alkalinity_expressed_as_mole_equivalent.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_preformed_alkalinity_expressed_as_mole_equivalent", + "id": "sea_water_preformed_alkalinity_expressed_as_mole_equivalent", "type": "standard_name", "name": "sea_water_preformed_alkalinity_expressed_as_mole_equivalent", "description": "\"Mole concentration\" means the number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Alkalinity\" refers to total alkalinity equivalent concentration, including carbonate, borate, phosphorus, silicon, and nitrogen components. The subduction and subsequent transport of surface water carry into the interior ocean considerable quantities of alkalinity, which is entirely independent of biological activity (such as organic decomposition and oxidation) after the water leaves the sea surface. Such alkalinity is termed \u201cpreformed\u201d alkalinity (Redfield,1942).", diff --git a/data_descriptors/standard_name/sea_water_preformed_salinity.json b/data_descriptors/standard_name/sea_water_preformed_salinity.json index b9f1bd53a..ba4f3579e 100644 --- a/data_descriptors/standard_name/sea_water_preformed_salinity.json +++ b/data_descriptors/standard_name/sea_water_preformed_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_preformed_salinity", + "id": "sea_water_preformed_salinity", "type": "standard_name", "name": "sea_water_preformed_salinity", "description": "Preformed Salinity, S*, is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the Intergovernmental Oceanographic Commission (IOC). Preformed Salinity is a salinity variable that is designed to be as conservative as possible, by removing the estimated biogeochemical influences on the sea water composition. Preformed Salinity is Absolute Salinity, S_A (which has the standard name sea_water_absolute_salinity), minus all contributions to sea water composition from biogeochemical processes. Preformed Salinity is the mass fraction of dissolved material in sea water. Reference: www.teos-10.org; Pawlowicz et al., 2011 doi: 10.5194/os-7-363-2011; Wright et al., 2011 doi: 10.5194/os-7-1-2011. There are also standard names for the precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 onwards), and sea_water_reference_salinity. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/sea_water_pressure.json b/data_descriptors/standard_name/sea_water_pressure.json index da1b5a979..8de38cc8b 100644 --- a/data_descriptors/standard_name/sea_water_pressure.json +++ b/data_descriptors/standard_name/sea_water_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_pressure", + "id": "sea_water_pressure", "type": "standard_name", "name": "sea_water_pressure", "description": "\"Sea water pressure\" is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present. For sea water pressure excluding the pressure due to overlying media other than sea water, the standard name sea_water_pressure_due_to_sea_water should be used.", diff --git a/data_descriptors/standard_name/sea_water_pressure_at_sea_floor.json b/data_descriptors/standard_name/sea_water_pressure_at_sea_floor.json index b2f58e7d8..2ce517591 100644 --- a/data_descriptors/standard_name/sea_water_pressure_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_pressure_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_pressure_at_sea_floor", + "id": "sea_water_pressure_at_sea_floor", "type": "standard_name", "name": "sea_water_pressure_at_sea_floor", "description": "\"Sea water pressure\" is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present.", diff --git a/data_descriptors/standard_name/sea_water_pressure_at_sea_water_surface.json b/data_descriptors/standard_name/sea_water_pressure_at_sea_water_surface.json index 6bd180661..88189011d 100644 --- a/data_descriptors/standard_name/sea_water_pressure_at_sea_water_surface.json +++ b/data_descriptors/standard_name/sea_water_pressure_at_sea_water_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_pressure_at_sea_water_surface", + "id": "sea_water_pressure_at_sea_water_surface", "type": "standard_name", "name": "sea_water_pressure_at_sea_water_surface", "description": "The phrase \"sea water surface\" means the upper boundary of the liquid portion of an ocean or sea, including the boundary to floating ice if present. \"Sea water pressure\" is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present.", diff --git a/data_descriptors/standard_name/sea_water_pressure_due_to_sea_water.json b/data_descriptors/standard_name/sea_water_pressure_due_to_sea_water.json index e21909125..42e37dc72 100644 --- a/data_descriptors/standard_name/sea_water_pressure_due_to_sea_water.json +++ b/data_descriptors/standard_name/sea_water_pressure_due_to_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_pressure_due_to_sea_water", + "id": "sea_water_pressure_due_to_sea_water", "type": "standard_name", "name": "sea_water_pressure_due_to_sea_water", "description": "The pressure that exists in the medium of sea water due to overlying sea water. Excludes the pressure due to sea ice, air and any other medium that may be present. For sea water pressure including the pressure due to overlying media other than sea water, the standard name sea_water_pressure should be used.", diff --git a/data_descriptors/standard_name/sea_water_redistributed_conservative_temperature.json b/data_descriptors/standard_name/sea_water_redistributed_conservative_temperature.json index a3788d031..1d72b714e 100644 --- a/data_descriptors/standard_name/sea_water_redistributed_conservative_temperature.json +++ b/data_descriptors/standard_name/sea_water_redistributed_conservative_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_redistributed_conservative_temperature", + "id": "sea_water_redistributed_conservative_temperature", "type": "standard_name", "name": "sea_water_redistributed_conservative_temperature", "description": "The quantity with standard name sea_water_redistributed_conservative_temperature is a passive tracer in an ocean model which is subject to an externally imposed perturbative surface heat flux. The passive tracer is initialised to the conservative temperature in the control climate before the perturbation is imposed. Its surface flux is the heat flux from the atmosphere, not including the imposed perturbation, and is converted to a passive tracer increment as if it were being added to conservative temperature. The passive tracer is transported within the ocean as if it were conservative temperature. The passive tracer records redistributed heat, as described for the CMIP6 FAFMIP experiment (doi:10.5194/gmd-9-3993-2016), following earlier ideas. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_redistributed_potential_temperature.json b/data_descriptors/standard_name/sea_water_redistributed_potential_temperature.json index f3daa7337..1e2e0d94c 100644 --- a/data_descriptors/standard_name/sea_water_redistributed_potential_temperature.json +++ b/data_descriptors/standard_name/sea_water_redistributed_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_redistributed_potential_temperature", + "id": "sea_water_redistributed_potential_temperature", "type": "standard_name", "name": "sea_water_redistributed_potential_temperature", "description": "The quantity with standard name sea_water_redistributed_potential_temperature is a passive tracer in an ocean model which is subject to an externally imposed perturbative surface heat flux. The passive tracer is initialised to the potential temperature in the control climate before the perturbation is imposed. Its surface flux is the heat flux from the atmosphere, not including the imposed perturbation, and is converted to a passive tracer increment as if it were being added to potential temperature. The passive tracer is transported within the ocean as if it were potential temperature. The passive tracer records redistributed heat, as described for the CMIP6 FAFMIP experiment (doi:10.5194/gmd-9-3993-2016), following earlier ideas. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_reference_salinity.json b/data_descriptors/standard_name/sea_water_reference_salinity.json index 79ca98f37..84c076087 100644 --- a/data_descriptors/standard_name/sea_water_reference_salinity.json +++ b/data_descriptors/standard_name/sea_water_reference_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_reference_salinity", + "id": "sea_water_reference_salinity", "type": "standard_name", "name": "sea_water_reference_salinity", "description": "If a sea water sample has the Reference Composition (defined in Millero et al., 2008), then its Reference Salinity is the best available estimate of its Absolute Salinity. For general purposes, Reference Salinity is (35.16504 g kg-1)/35 times Practical Salinity. Reference: www.teos-10.org; Millero et al., 2008 doi: 10.1016/j.dsr.2007.10.001. There are also standard names for the precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity (used for salinity observations from 1978 onwards), sea_water_absolute_salinity, S_A, and sea_water_preformed_salinity, S_*. Salinity quantities that do not match any of the precise definitions should be given the more general standard name of sea_water_salinity.", diff --git a/data_descriptors/standard_name/sea_water_salinity.json b/data_descriptors/standard_name/sea_water_salinity.json index 2e74afbe4..8af64be52 100644 --- a/data_descriptors/standard_name/sea_water_salinity.json +++ b/data_descriptors/standard_name/sea_water_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_salinity", + "id": "sea_water_salinity", "type": "standard_name", "name": "sea_water_salinity", "description": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/sea_water_salinity_at_sea_floor.json b/data_descriptors/standard_name/sea_water_salinity_at_sea_floor.json index 670098527..7bcc62c85 100644 --- a/data_descriptors/standard_name/sea_water_salinity_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_salinity_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_salinity_at_sea_floor", + "id": "sea_water_salinity_at_sea_floor", "type": "standard_name", "name": "sea_water_salinity_at_sea_floor", "description": "The salinity at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements. Sea water salinity is the salt concentration of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. Practical salinity units are dimensionless. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/sea_water_sigma_t.json b/data_descriptors/standard_name/sea_water_sigma_t.json index 658bdb386..1537f82c2 100644 --- a/data_descriptors/standard_name/sea_water_sigma_t.json +++ b/data_descriptors/standard_name/sea_water_sigma_t.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_sigma_t", + "id": "sea_water_sigma_t", "type": "standard_name", "name": "sea_water_sigma_t", "description": "Sigma-t of sea water is the density of water at atmospheric pressure (i.e. the surface) having the same temperature and salinity, minus 1000 kg m-3. Note that sea water sigma is not the same quantity as the dimensionless ocean sigma coordinate (see Appendix D of the CF convention), for which there is another standard name.", diff --git a/data_descriptors/standard_name/sea_water_sigma_t_difference.json b/data_descriptors/standard_name/sea_water_sigma_t_difference.json index b314661df..5e4584d81 100644 --- a/data_descriptors/standard_name/sea_water_sigma_t_difference.json +++ b/data_descriptors/standard_name/sea_water_sigma_t_difference.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_sigma_t_difference", + "id": "sea_water_sigma_t_difference", "type": "standard_name", "name": "sea_water_sigma_t_difference", "description": "Sigma-t of sea water is the density of water at atmospheric pressure (i.e. the surface) having the same temperature and salinity, minus 1000 kg m-3.", diff --git a/data_descriptors/standard_name/sea_water_sigma_theta.json b/data_descriptors/standard_name/sea_water_sigma_theta.json index 1492b771d..524b6e2ee 100644 --- a/data_descriptors/standard_name/sea_water_sigma_theta.json +++ b/data_descriptors/standard_name/sea_water_sigma_theta.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_sigma_theta", + "id": "sea_water_sigma_theta", "type": "standard_name", "name": "sea_water_sigma_theta", "description": "Sigma-theta of sea water is the potential density (i.e. the density when moved adiabatically to a reference pressure) of water having the same temperature and salinity, minus 1000 kg m-3. Note that sea water sigma is not the same quantity as the dimensionless ocean sigma coordinate (see Appendix D of the CF convention), for which there is another standard name. To specify the reference pressure to which the quantity applies, provide a scalar coordinate variable with standard name reference_pressure.", diff --git a/data_descriptors/standard_name/sea_water_sigma_theta_difference.json b/data_descriptors/standard_name/sea_water_sigma_theta_difference.json index b1bb74f38..741566838 100644 --- a/data_descriptors/standard_name/sea_water_sigma_theta_difference.json +++ b/data_descriptors/standard_name/sea_water_sigma_theta_difference.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_sigma_theta_difference", + "id": "sea_water_sigma_theta_difference", "type": "standard_name", "name": "sea_water_sigma_theta_difference", "description": "Sigma-theta of sea water is the potential density (i.e. the density when moved adiabatically to a reference pressure) of water having the same temperature and salinity, minus 1000 kg m-3.", diff --git a/data_descriptors/standard_name/sea_water_specific_potential_enthalpy.json b/data_descriptors/standard_name/sea_water_specific_potential_enthalpy.json index 8cc0c16b4..ed912d972 100644 --- a/data_descriptors/standard_name/sea_water_specific_potential_enthalpy.json +++ b/data_descriptors/standard_name/sea_water_specific_potential_enthalpy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_specific_potential_enthalpy", + "id": "sea_water_specific_potential_enthalpy", "type": "standard_name", "name": "sea_water_specific_potential_enthalpy", "description": "The potential enthalpy of a sea water parcel is the specific enthalpy after an adiabatic and isohaline change in pressure from its in situ pressure to the sea pressure p = 0 dbar. \"specific\" means per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2.", diff --git a/data_descriptors/standard_name/sea_water_speed.json b/data_descriptors/standard_name/sea_water_speed.json index 3266733fa..bb211cf01 100644 --- a/data_descriptors/standard_name/sea_water_speed.json +++ b/data_descriptors/standard_name/sea_water_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_speed", + "id": "sea_water_speed", "type": "standard_name", "name": "sea_water_speed", "description": "Speed is the magnitude of velocity.", diff --git a/data_descriptors/standard_name/sea_water_speed_at_sea_floor.json b/data_descriptors/standard_name/sea_water_speed_at_sea_floor.json index 41e7ef204..ec30d5153 100644 --- a/data_descriptors/standard_name/sea_water_speed_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_speed_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_speed_at_sea_floor", + "id": "sea_water_speed_at_sea_floor", "type": "standard_name", "name": "sea_water_speed_at_sea_floor", "description": "Speed is the magnitude of velocity. The speed at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements.", diff --git a/data_descriptors/standard_name/sea_water_speed_due_to_ekman_drift.json b/data_descriptors/standard_name/sea_water_speed_due_to_ekman_drift.json index 482a0b6e6..dc2e91339 100644 --- a/data_descriptors/standard_name/sea_water_speed_due_to_ekman_drift.json +++ b/data_descriptors/standard_name/sea_water_speed_due_to_ekman_drift.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_speed_due_to_ekman_drift", + "id": "sea_water_speed_due_to_ekman_drift", "type": "standard_name", "name": "sea_water_speed_due_to_ekman_drift", "description": "Speed is the magnitude of velocity. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Ekman drift\" is the movement of a layer of water (the Ekman layer) due to the combination of wind stress at the sea surface and the Coriolis effect. Ekman drift is to the right of the wind direction in the Northern Hemisphere and the left in the Southern Hemisphere. Reference: https://www.open.edu/openlearn/science-maths-technology/the-oceans/content-section-4.3.", diff --git a/data_descriptors/standard_name/sea_water_speed_due_to_tides.json b/data_descriptors/standard_name/sea_water_speed_due_to_tides.json index f8da17212..bfbe3304b 100644 --- a/data_descriptors/standard_name/sea_water_speed_due_to_tides.json +++ b/data_descriptors/standard_name/sea_water_speed_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_speed_due_to_tides", + "id": "sea_water_speed_due_to_tides", "type": "standard_name", "name": "sea_water_speed_due_to_tides", "description": "Speed is the magnitude of velocity. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components.", diff --git a/data_descriptors/standard_name/sea_water_speed_shear.json b/data_descriptors/standard_name/sea_water_speed_shear.json index 7727e7d90..aaa266478 100644 --- a/data_descriptors/standard_name/sea_water_speed_shear.json +++ b/data_descriptors/standard_name/sea_water_speed_shear.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_speed_shear", + "id": "sea_water_speed_shear", "type": "standard_name", "name": "sea_water_speed_shear", "description": "Speed is the magnitude of velocity. Sea water speed shear is the derivative of sea water speed with respect to depth.", diff --git a/data_descriptors/standard_name/sea_water_temperature.json b/data_descriptors/standard_name/sea_water_temperature.json index 5c2e4e85e..cba8f35bc 100644 --- a/data_descriptors/standard_name/sea_water_temperature.json +++ b/data_descriptors/standard_name/sea_water_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_temperature", + "id": "sea_water_temperature", "type": "standard_name", "name": "sea_water_temperature", "description": "Sea water temperature is the in situ temperature of the sea water. To specify the depth at which the temperature applies use a vertical coordinate variable or scalar coordinate variable. There are standard names for sea_surface_temperature, sea_surface_skin_temperature, sea_surface_subskin_temperature and sea_surface_foundation_temperature which can be used to describe data located at the specified surfaces. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_temperature_anomaly.json b/data_descriptors/standard_name/sea_water_temperature_anomaly.json index 8c0ae639b..8d480b129 100644 --- a/data_descriptors/standard_name/sea_water_temperature_anomaly.json +++ b/data_descriptors/standard_name/sea_water_temperature_anomaly.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_temperature_anomaly", + "id": "sea_water_temperature_anomaly", "type": "standard_name", "name": "sea_water_temperature_anomaly", "description": "The term \"anomaly\" means difference from climatology. Sea water temperature is the in situ temperature of the sea water. To specify the depth at which the temperature anomaly applies, use a vertical coordinate variable or scalar coordinate variable. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_temperature_at_sea_floor.json b/data_descriptors/standard_name/sea_water_temperature_at_sea_floor.json index a10d5ea49..8c5adbb55 100644 --- a/data_descriptors/standard_name/sea_water_temperature_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_temperature_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_temperature_at_sea_floor", + "id": "sea_water_temperature_at_sea_floor", "type": "standard_name", "name": "sea_water_temperature_at_sea_floor", "description": "Sea water temperature is the in situ temperature of the sea water. The temperature at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_temperature_difference.json b/data_descriptors/standard_name/sea_water_temperature_difference.json index 3980257d7..55123ab04 100644 --- a/data_descriptors/standard_name/sea_water_temperature_difference.json +++ b/data_descriptors/standard_name/sea_water_temperature_difference.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_temperature_difference", + "id": "sea_water_temperature_difference", "type": "standard_name", "name": "sea_water_temperature_difference", "description": "Sea water temperature is the in situ temperature of the sea water. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/sea_water_transport_across_line.json b/data_descriptors/standard_name/sea_water_transport_across_line.json index 3800f9351..e2a0c7fd3 100644 --- a/data_descriptors/standard_name/sea_water_transport_across_line.json +++ b/data_descriptors/standard_name/sea_water_transport_across_line.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_transport_across_line", + "id": "sea_water_transport_across_line", "type": "standard_name", "name": "sea_water_transport_across_line", "description": "Transport across_line means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport.", diff --git a/data_descriptors/standard_name/sea_water_turbidity.json b/data_descriptors/standard_name/sea_water_turbidity.json index 18627527d..2f5687021 100644 --- a/data_descriptors/standard_name/sea_water_turbidity.json +++ b/data_descriptors/standard_name/sea_water_turbidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_turbidity", + "id": "sea_water_turbidity", "type": "standard_name", "name": "sea_water_turbidity", "description": "Turbidity is a dimensionless quantity which is expressed in NTU (Nephelometric Turbidity Units). Turbidity expressed in NTU is the proportion of white light scattered back to a transceiver by the particulate load in a body of water, represented on an arbitrary scale referenced against measurements made in the laboratory on aqueous suspensions of formazine beads. Sea water turbidity may also be measured by the quantity with standard name secchi_depth_of_sea_water.", diff --git a/data_descriptors/standard_name/sea_water_velocity_from_direction.json b/data_descriptors/standard_name/sea_water_velocity_from_direction.json index e790c1732..703dadaa9 100644 --- a/data_descriptors/standard_name/sea_water_velocity_from_direction.json +++ b/data_descriptors/standard_name/sea_water_velocity_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_velocity_from_direction", + "id": "sea_water_velocity_from_direction", "type": "standard_name", "name": "sea_water_velocity_from_direction", "description": "A velocity is a vector quantity. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_water_velocity_to_direction.json b/data_descriptors/standard_name/sea_water_velocity_to_direction.json index 3e490cbf7..2233afea8 100644 --- a/data_descriptors/standard_name/sea_water_velocity_to_direction.json +++ b/data_descriptors/standard_name/sea_water_velocity_to_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_velocity_to_direction", + "id": "sea_water_velocity_to_direction", "type": "standard_name", "name": "sea_water_velocity_to_direction", "description": "A velocity is a vector quantity. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/sea_water_velocity_to_direction_at_sea_floor.json b/data_descriptors/standard_name/sea_water_velocity_to_direction_at_sea_floor.json index 68070d971..a23a69769 100644 --- a/data_descriptors/standard_name/sea_water_velocity_to_direction_at_sea_floor.json +++ b/data_descriptors/standard_name/sea_water_velocity_to_direction_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_velocity_to_direction_at_sea_floor", + "id": "sea_water_velocity_to_direction_at_sea_floor", "type": "standard_name", "name": "sea_water_velocity_to_direction_at_sea_floor", "description": "A velocity is a vector quantity. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The direction at the sea floor is that adjacent to the ocean bottom, which would be the deepest grid cell in an ocean model and within the benthic boundary layer for measurements.", diff --git a/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_ekman_drift.json b/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_ekman_drift.json index 35149939f..d1f92d601 100644 --- a/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_ekman_drift.json +++ b/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_ekman_drift.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_velocity_to_direction_due_to_ekman_drift", + "id": "sea_water_velocity_to_direction_due_to_ekman_drift", "type": "standard_name", "name": "sea_water_velocity_to_direction_due_to_ekman_drift", "description": "A velocity is a vector quantity. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Ekman drift\" is the movement of a layer of water (the Ekman layer) due to the combination of wind stress at the sea surface and the Coriolis effect. Ekman drift is to the right of the wind direction in the Northern Hemisphere and the left in the Southern Hemisphere. Reference: https://www.open.edu/openlearn/science-maths-technology/the-oceans/content-section-4.3.", diff --git a/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_tides.json b/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_tides.json index 92ba20c81..6d1b055ef 100644 --- a/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_tides.json +++ b/data_descriptors/standard_name/sea_water_velocity_to_direction_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_velocity_to_direction_due_to_tides", + "id": "sea_water_velocity_to_direction_due_to_tides", "type": "standard_name", "name": "sea_water_velocity_to_direction_due_to_tides", "description": "A velocity is a vector quantity. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components.", diff --git a/data_descriptors/standard_name/sea_water_volume.json b/data_descriptors/standard_name/sea_water_volume.json index b1cfe3914..61ca95da3 100644 --- a/data_descriptors/standard_name/sea_water_volume.json +++ b/data_descriptors/standard_name/sea_water_volume.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_volume", + "id": "sea_water_volume", "type": "standard_name", "name": "sea_water_volume", "description": "The quantity with standard name \"sea_water_volume\" is the total volume of liquid seawater in the global oceans, including enclosed seas.", diff --git a/data_descriptors/standard_name/sea_water_volume_fraction.json b/data_descriptors/standard_name/sea_water_volume_fraction.json index 6335a6e97..43ebcbfc6 100644 --- a/data_descriptors/standard_name/sea_water_volume_fraction.json +++ b/data_descriptors/standard_name/sea_water_volume_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_volume_fraction", + "id": "sea_water_volume_fraction", "type": "standard_name", "name": "sea_water_volume_fraction", "description": "\"X_volume_fraction\" means the fraction of volume occupied by X. It is evaluated as the volume of interest divided by the grid cell volume. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. A data variable with standard name sea_water_volume_fraction is used to store the fraction of a grid cell underlying sea-water, for example, where part of the grid cell is occupied by land or to record ocean volume on a model's native grid following a regridding operation.", diff --git a/data_descriptors/standard_name/sea_water_x_velocity.json b/data_descriptors/standard_name/sea_water_x_velocity.json index c3cc9cd5d..c6d4a9ca2 100644 --- a/data_descriptors/standard_name/sea_water_x_velocity.json +++ b/data_descriptors/standard_name/sea_water_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_x_velocity", + "id": "sea_water_x_velocity", "type": "standard_name", "name": "sea_water_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x.", diff --git a/data_descriptors/standard_name/sea_water_x_velocity_due_to_parameterized_mesoscale_eddies.json b/data_descriptors/standard_name/sea_water_x_velocity_due_to_parameterized_mesoscale_eddies.json index 920d81c73..cbb7a9fc9 100644 --- a/data_descriptors/standard_name/sea_water_x_velocity_due_to_parameterized_mesoscale_eddies.json +++ b/data_descriptors/standard_name/sea_water_x_velocity_due_to_parameterized_mesoscale_eddies.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_x_velocity_due_to_parameterized_mesoscale_eddies", + "id": "sea_water_x_velocity_due_to_parameterized_mesoscale_eddies", "type": "standard_name", "name": "sea_water_x_velocity_due_to_parameterized_mesoscale_eddies", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddies occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddies are represented in ocean models using schemes such as the Gent-McWilliams scheme. sea_water_x_velocity_due_to_parameterized_mesoscale_eddies is used in some parameterisations of lateral diffusion in the ocean.", diff --git a/data_descriptors/standard_name/sea_water_y_velocity.json b/data_descriptors/standard_name/sea_water_y_velocity.json index 31e9371ca..4c98accdf 100644 --- a/data_descriptors/standard_name/sea_water_y_velocity.json +++ b/data_descriptors/standard_name/sea_water_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_y_velocity", + "id": "sea_water_y_velocity", "type": "standard_name", "name": "sea_water_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y.", diff --git a/data_descriptors/standard_name/sea_water_y_velocity_due_to_parameterized_mesoscale_eddies.json b/data_descriptors/standard_name/sea_water_y_velocity_due_to_parameterized_mesoscale_eddies.json index 0dbd0d080..fe86f6bf4 100644 --- a/data_descriptors/standard_name/sea_water_y_velocity_due_to_parameterized_mesoscale_eddies.json +++ b/data_descriptors/standard_name/sea_water_y_velocity_due_to_parameterized_mesoscale_eddies.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sea_water_y_velocity_due_to_parameterized_mesoscale_eddies", + "id": "sea_water_y_velocity_due_to_parameterized_mesoscale_eddies", "type": "standard_name", "name": "sea_water_y_velocity_due_to_parameterized_mesoscale_eddies", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddies occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddies are represented in ocean models using schemes such as the Gent-McWilliams scheme. sea_water_y_velocity_due_to_parameterized_mesoscale_eddies is used in some parameterisations of lateral diffusion in the ocean.", diff --git a/data_descriptors/standard_name/secchi_depth_of_sea_water.json b/data_descriptors/standard_name/secchi_depth_of_sea_water.json index f590f3b68..003b8df7f 100644 --- a/data_descriptors/standard_name/secchi_depth_of_sea_water.json +++ b/data_descriptors/standard_name/secchi_depth_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/secchi_depth_of_sea_water", + "id": "secchi_depth_of_sea_water", "type": "standard_name", "name": "secchi_depth_of_sea_water", "description": "Depth is the vertical distance below the surface. A Secchi disk is a patterned disk that is used to measure water transparency, also called turbidity, in oceans and lakes. The disk is lowered into the water and the depth at which the pattern is no longer visible is the called the secchi depth. Sea water turbidity may also be measured by the quantity with standard name sea_water_turbidity.", diff --git a/data_descriptors/standard_name/sensor_azimuth_angle.json b/data_descriptors/standard_name/sensor_azimuth_angle.json index 698fcdf8b..319aac7eb 100644 --- a/data_descriptors/standard_name/sensor_azimuth_angle.json +++ b/data_descriptors/standard_name/sensor_azimuth_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_azimuth_angle", + "id": "sensor_azimuth_angle", "type": "standard_name", "name": "sensor_azimuth_angle", "description": "sensor_azimuth_angle is the horizontal angle between the line of sight from the observation point to the sensor and a reference direction at the observation point, which is often due north. The angle is measured clockwise positive, starting from the reference direction. A comment attribute should be added to a data variable with this standard name to specify the reference direction. A standard name also exists for platform_azimuth_angle, where \"platform\" refers to the vehicle from which observations are made e.g. aeroplane, ship, or satellite. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated azimuth angle.", diff --git a/data_descriptors/standard_name/sensor_band_central_radiation_frequency.json b/data_descriptors/standard_name/sensor_band_central_radiation_frequency.json index 94e7b605b..c3505cc0e 100644 --- a/data_descriptors/standard_name/sensor_band_central_radiation_frequency.json +++ b/data_descriptors/standard_name/sensor_band_central_radiation_frequency.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_band_central_radiation_frequency", + "id": "sensor_band_central_radiation_frequency", "type": "standard_name", "name": "sensor_band_central_radiation_frequency", "description": "sensor_band_central_radiation_frequency is the central frequency of a sensor's band, calculated as the first moment of the band's normalized spectral response function.", diff --git a/data_descriptors/standard_name/sensor_band_central_radiation_wavelength.json b/data_descriptors/standard_name/sensor_band_central_radiation_wavelength.json index dbebf2ea0..111388f44 100644 --- a/data_descriptors/standard_name/sensor_band_central_radiation_wavelength.json +++ b/data_descriptors/standard_name/sensor_band_central_radiation_wavelength.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_band_central_radiation_wavelength", + "id": "sensor_band_central_radiation_wavelength", "type": "standard_name", "name": "sensor_band_central_radiation_wavelength", "description": "sensor_band_central_radiation_wavelength is the central wavelength of a sensor's band, calculated as the first moment of the band's normalized spectral response function.", diff --git a/data_descriptors/standard_name/sensor_band_central_radiation_wavenumber.json b/data_descriptors/standard_name/sensor_band_central_radiation_wavenumber.json index 4bfd5eaee..4aa64793b 100644 --- a/data_descriptors/standard_name/sensor_band_central_radiation_wavenumber.json +++ b/data_descriptors/standard_name/sensor_band_central_radiation_wavenumber.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_band_central_radiation_wavenumber", + "id": "sensor_band_central_radiation_wavenumber", "type": "standard_name", "name": "sensor_band_central_radiation_wavenumber", "description": "sensor_band_central_radiation_wavenumber is the central wavenumber of a sensor's band, calculated as the first moment of the band's normalized spectral response function.", diff --git a/data_descriptors/standard_name/sensor_band_identifier.json b/data_descriptors/standard_name/sensor_band_identifier.json index f71b3b006..85c867833 100644 --- a/data_descriptors/standard_name/sensor_band_identifier.json +++ b/data_descriptors/standard_name/sensor_band_identifier.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_band_identifier", + "id": "sensor_band_identifier", "type": "standard_name", "name": "sensor_band_identifier", "description": "A variable with the standard name of sensor_band_identifier contains strings which give the alphanumeric identifier of a sensor band. These strings have not yet been standardised.", diff --git a/data_descriptors/standard_name/sensor_view_angle.json b/data_descriptors/standard_name/sensor_view_angle.json index ac06a141d..872a9a471 100644 --- a/data_descriptors/standard_name/sensor_view_angle.json +++ b/data_descriptors/standard_name/sensor_view_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_view_angle", + "id": "sensor_view_angle", "type": "standard_name", "name": "sensor_view_angle", "description": "Sensor view angle is the angle between the line of sight from the sensor and the direction straight vertically down. Zero view angle means looking directly beneath the sensor. There is no standardized sign convention for sensor_view_angle. A standard name also exists for platform_view_angle, where \"platform\" refers to the vehicle from which observations are made e.g. aeroplane, ship, or satellite. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated view angle.", diff --git a/data_descriptors/standard_name/sensor_zenith_angle.json b/data_descriptors/standard_name/sensor_zenith_angle.json index 610fcd2b5..8795917b8 100644 --- a/data_descriptors/standard_name/sensor_zenith_angle.json +++ b/data_descriptors/standard_name/sensor_zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sensor_zenith_angle", + "id": "sensor_zenith_angle", "type": "standard_name", "name": "sensor_zenith_angle", "description": "sensor_zenith_angle is the angle between the line of sight to the sensor and the local zenith at the observation target. This angle is measured starting from directly overhead and its range is from zero (directly overhead the observation target) to 180 degrees (directly below the observation target). Local zenith is a line perpendicular to the Earth's surface at a given location. \"Observation target\" means a location on the Earth defined by the sensor performing the observations. A standard name also exists for platform_zenith_angle, where \"platform\" refers to the vehicle from which observations are made e.g. aeroplane, ship, or satellite. For some viewing geometries the sensor and the platform cannot be assumed to be close enough to neglect the difference in calculated zenith angle.", diff --git a/data_descriptors/standard_name/shallow_convection_time_fraction.json b/data_descriptors/standard_name/shallow_convection_time_fraction.json index c8d3d49f9..59db7921f 100644 --- a/data_descriptors/standard_name/shallow_convection_time_fraction.json +++ b/data_descriptors/standard_name/shallow_convection_time_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/shallow_convection_time_fraction", + "id": "shallow_convection_time_fraction", "type": "standard_name", "name": "shallow_convection_time_fraction", "description": "\"Time fraction\" means a fraction of a time interval. The interval in question must be specified by the values or bounds of the time coordinate variable associated with the data. \"X_time_fraction\" means the fraction of the time interval during which X occurs.", diff --git a/data_descriptors/standard_name/shallow_convective_cloud_base_altitude.json b/data_descriptors/standard_name/shallow_convective_cloud_base_altitude.json index d2238bd24..c80d2e403 100644 --- a/data_descriptors/standard_name/shallow_convective_cloud_base_altitude.json +++ b/data_descriptors/standard_name/shallow_convective_cloud_base_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/shallow_convective_cloud_base_altitude", + "id": "shallow_convective_cloud_base_altitude", "type": "standard_name", "name": "shallow_convective_cloud_base_altitude", "description": "The phrase \"cloud_base\" refers to the base of the lowest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. Shallow convective cloud is nonprecipitating cumulus cloud with a cloud top below 3000m above the surface produced by the convection schemes in an atmosphere model. Some atmosphere models differentiate between shallow and deep convection.", diff --git a/data_descriptors/standard_name/shallow_convective_cloud_top_altitude.json b/data_descriptors/standard_name/shallow_convective_cloud_top_altitude.json index 737740f9e..9da776915 100644 --- a/data_descriptors/standard_name/shallow_convective_cloud_top_altitude.json +++ b/data_descriptors/standard_name/shallow_convective_cloud_top_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/shallow_convective_cloud_top_altitude", + "id": "shallow_convective_cloud_top_altitude", "type": "standard_name", "name": "shallow_convective_cloud_top_altitude", "description": "The phrase \"cloud_top\" refers to the top of the highest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. Shallow convective cloud is nonprecipitating cumulus cloud with a cloud top below 3000m above the surface produced by the convection schemes in an atmosphere model. Some atmosphere models differentiate between shallow and deep convection.", diff --git a/data_descriptors/standard_name/shallow_convective_precipitation_flux.json b/data_descriptors/standard_name/shallow_convective_precipitation_flux.json index 4007b0175..0f3ce235e 100644 --- a/data_descriptors/standard_name/shallow_convective_precipitation_flux.json +++ b/data_descriptors/standard_name/shallow_convective_precipitation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/shallow_convective_precipitation_flux", + "id": "shallow_convective_precipitation_flux", "type": "standard_name", "name": "shallow_convective_precipitation_flux", "description": "Convective precipitation is that produced by the convection schemes in an atmosphere model. Some atmosphere models differentiate between shallow and deep convection. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/shear_strength_of_frozen_soil.json b/data_descriptors/standard_name/shear_strength_of_frozen_soil.json index 702a570fa..01db9bdde 100644 --- a/data_descriptors/standard_name/shear_strength_of_frozen_soil.json +++ b/data_descriptors/standard_name/shear_strength_of_frozen_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/shear_strength_of_frozen_soil", + "id": "shear_strength_of_frozen_soil", "type": "standard_name", "name": "shear_strength_of_frozen_soil", "description": "Shear strength is the amount of force applied to a normal plane required to bring a frozen soil to failure along a tangential plane. Shear strength depends on the angle of friction and cohesion of the soil.", diff --git a/data_descriptors/standard_name/shear_strength_of_soil.json b/data_descriptors/standard_name/shear_strength_of_soil.json index b1c7d45d3..be99eea94 100644 --- a/data_descriptors/standard_name/shear_strength_of_soil.json +++ b/data_descriptors/standard_name/shear_strength_of_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/shear_strength_of_soil", + "id": "shear_strength_of_soil", "type": "standard_name", "name": "shear_strength_of_soil", "description": "Shear strength is the amount of force applied to a normal plane required to bring the soil to failure along a tangential plane. Shear strength depends on the angle of friction and cohesion of the soil.", diff --git a/data_descriptors/standard_name/signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water.json b/data_descriptors/standard_name/signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water.json index 6620ece0b..0a8e1bac2 100644 --- a/data_descriptors/standard_name/signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water.json +++ b/data_descriptors/standard_name/signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water", + "id": "signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water", "type": "standard_name", "name": "signal_intensity_from_multibeam_acoustic_doppler_velocity_sensor_in_sea_water", "description": "The magnitude of an acoustic signal emitted by the instrument toward a reflecting surface and received again by the instrument.", diff --git a/data_descriptors/standard_name/silicate_mass_transport_in_river_channel.json b/data_descriptors/standard_name/silicate_mass_transport_in_river_channel.json index ba6b27ce4..f5b802f04 100644 --- a/data_descriptors/standard_name/silicate_mass_transport_in_river_channel.json +++ b/data_descriptors/standard_name/silicate_mass_transport_in_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/silicate_mass_transport_in_river_channel", + "id": "silicate_mass_transport_in_river_channel", "type": "standard_name", "name": "silicate_mass_transport_in_river_channel", "description": "The amount of silicate mass transported in the river channels from land into the ocean. This quantity can be provided at a certain location within the river network and floodplain (over land) or at the river mouth (over ocean) where the river enters the ocean. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/single_scattering_albedo_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/single_scattering_albedo_in_air_due_to_ambient_aerosol_particles.json index 058ea17f5..7b1fd2bea 100644 --- a/data_descriptors/standard_name/single_scattering_albedo_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/single_scattering_albedo_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/single_scattering_albedo_in_air_due_to_ambient_aerosol_particles", + "id": "single_scattering_albedo_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "single_scattering_albedo_in_air_due_to_ambient_aerosol_particles", "description": "\"Single scattering albedo\" is the fraction of radiation in an incident light beam scattered by the particles of an aerosol reference volume for a given wavelength. It is the ratio of the scattering and the extinction coefficients of the aerosol particles in the reference volume. A coordinate variable with a standard name of radiation_wavelength or radiation_frequency should be included to specify either the wavelength or frequency. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air.json index 17421b3c3..3f0118207 100644 --- a/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air", + "id": "singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "singular_value_of_remote_sensing_averaging_kernel_mole_fraction_of_methane_in_air", "description": "Singular values of the matrix representing the remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000).", diff --git a/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json index 729c97bd6..fc73f0517 100644 --- a/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", + "id": "singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "singular_value_of_remote_sensing_averaging_kernel_of_logarithm_of_mole_fraction_of_methane_in_air", "description": "Singular values of the matrix representing the remote sensing averaging kernels (Weber 2019; Schneider et al., 2022) of the methane mole fractions obtained by a remote sensing observation (changes of methane in the retrieved atmosphere relative to the changes of methane in the true atmosphere, Rodgers 2000).", diff --git a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water.json b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water.json index d177b4d24..c0c4a8732 100644 --- a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water", + "id": "sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water", "type": "standard_name", "name": "sinking_mass_flux_of_particulate_biogenic_silica_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Particulate means suspended solids of all sizes. Biogenic silica is a hydrated form of silica (silicon dioxide) with the chemical formula SiO2.nH2O sometimes referred to as opaline silica or opal. It is created by biological processes and in sea water it is predominantly the skeletal material of diatoms.", diff --git a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_carbon_in_sea_water.json b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_carbon_in_sea_water.json index ca533f665..0faf70f00 100644 --- a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mass_flux_of_particulate_carbon_in_sea_water", + "id": "sinking_mass_flux_of_particulate_carbon_in_sea_water", "type": "standard_name", "name": "sinking_mass_flux_of_particulate_carbon_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water.json b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water.json index 1fbed9404..d59d480e6 100644 --- a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water", + "id": "sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water", "type": "standard_name", "name": "sinking_mass_flux_of_particulate_inorganic_carbon_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Particulate means suspended solids of all sizes. Particulate inorganic carbon is carbon bound in molecules ionically that may be liberated from the particles as carbon dioxide by acidification.", diff --git a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_matter_in_sea_water.json b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_matter_in_sea_water.json index 13c184f51..bf3bae6d3 100644 --- a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_matter_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_matter_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mass_flux_of_particulate_matter_in_sea_water", + "id": "sinking_mass_flux_of_particulate_matter_in_sea_water", "type": "standard_name", "name": "sinking_mass_flux_of_particulate_matter_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", diff --git a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_nitrogen_in_sea_water.json b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_nitrogen_in_sea_water.json index f11c612b6..c7c59a580 100644 --- a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mass_flux_of_particulate_nitrogen_in_sea_water", + "id": "sinking_mass_flux_of_particulate_nitrogen_in_sea_water", "type": "standard_name", "name": "sinking_mass_flux_of_particulate_nitrogen_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_phosphorus_in_sea_water.json b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_phosphorus_in_sea_water.json index 6a6546020..6ceaaad83 100644 --- a/data_descriptors/standard_name/sinking_mass_flux_of_particulate_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mass_flux_of_particulate_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mass_flux_of_particulate_phosphorus_in_sea_water", + "id": "sinking_mass_flux_of_particulate_phosphorus_in_sea_water", "type": "standard_name", "name": "sinking_mass_flux_of_particulate_phosphorus_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Particulate means suspended solids of all sizes.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water.json index 583ab75d3..45c712e3b 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water", + "id": "sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water", "description": "The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water.json index 21162a865..152c64aa3 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water", + "id": "sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water", "description": "The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_iron_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_iron_in_sea_water.json index ead725b2b..0cebd2f59 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_iron_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_iron_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_particulate_iron_in_sea_water", + "id": "sinking_mole_flux_of_particulate_iron_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_particulate_iron_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water.json index 3f4c0a8aa..53ca2e2f8 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water", + "id": "sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water", "description": "The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water.json index 2291b622f..70292ecb1 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water", + "id": "sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sinking\" is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. \"Particulate organic nitrogen\" means the sum of all organic nitrogen compounds, which are solid or which are bound to solid particles. \"Organic nitrogen\", when measured, always refers to all nitrogen incorporated in carbon compounds in the sample. Models may use the term to refer to nitrogen contained in specific groups of organic compounds in which case the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water.json index 91cb385cd..1fc6ab5f8 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water", + "id": "sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", diff --git a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_silicon_in_sea_water.json b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_silicon_in_sea_water.json index b670aa8a3..276d9a28e 100644 --- a/data_descriptors/standard_name/sinking_mole_flux_of_particulate_silicon_in_sea_water.json +++ b/data_descriptors/standard_name/sinking_mole_flux_of_particulate_silicon_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sinking_mole_flux_of_particulate_silicon_in_sea_water", + "id": "sinking_mole_flux_of_particulate_silicon_in_sea_water", "type": "standard_name", "name": "sinking_mole_flux_of_particulate_silicon_in_sea_water", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", diff --git a/data_descriptors/standard_name/slow_soil_pool_mass_content_of_carbon.json b/data_descriptors/standard_name/slow_soil_pool_mass_content_of_carbon.json index 30d674ed3..30949e4b9 100644 --- a/data_descriptors/standard_name/slow_soil_pool_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/slow_soil_pool_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/slow_soil_pool_mass_content_of_carbon", + "id": "slow_soil_pool_mass_content_of_carbon", "type": "standard_name", "name": "slow_soil_pool_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used. Soil carbon is returned to the atmosphere as the organic matter decays. The decay process takes varying amounts of time depending on the composition of the organic matter, the temperature and the availability of moisture. A carbon \"soil pool\" means the carbon contained in organic matter which has a characteristic period over which it decays and releases carbon into the atmosphere. \"Slow soil pool\" refers to the decay of organic matter in soil with a characteristic period of more than a hundred years under reference climate conditions of a temperature of 20 degrees Celsius and no water limitations.", diff --git a/data_descriptors/standard_name/snow_area_fraction_viewable_from_above.json b/data_descriptors/standard_name/snow_area_fraction_viewable_from_above.json index c693599bd..34f74c225 100644 --- a/data_descriptors/standard_name/snow_area_fraction_viewable_from_above.json +++ b/data_descriptors/standard_name/snow_area_fraction_viewable_from_above.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/snow_area_fraction_viewable_from_above", + "id": "snow_area_fraction_viewable_from_above", "type": "standard_name", "name": "snow_area_fraction_viewable_from_above", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Snow \"viewable from above\" refers to the snow on objects or the ground as viewed from above, which excludes, for example, falling snow flakes and snow obscured by a canopy, vegetative cover, or other features resting on the surface.", diff --git a/data_descriptors/standard_name/snow_grain_size.json b/data_descriptors/standard_name/snow_grain_size.json index 733e0710c..f94192bab 100644 --- a/data_descriptors/standard_name/snow_grain_size.json +++ b/data_descriptors/standard_name/snow_grain_size.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/snow_grain_size", + "id": "snow_grain_size", "type": "standard_name", "name": "snow_grain_size", "description": null, diff --git a/data_descriptors/standard_name/snow_transport_across_line_due_to_sea_ice_dynamics.json b/data_descriptors/standard_name/snow_transport_across_line_due_to_sea_ice_dynamics.json index 2d6e02e82..1f0f81730 100644 --- a/data_descriptors/standard_name/snow_transport_across_line_due_to_sea_ice_dynamics.json +++ b/data_descriptors/standard_name/snow_transport_across_line_due_to_sea_ice_dynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/snow_transport_across_line_due_to_sea_ice_dynamics", + "id": "snow_transport_across_line_due_to_sea_ice_dynamics", "type": "standard_name", "name": "snow_transport_across_line_due_to_sea_ice_dynamics", "description": "Transport \"across_line\" means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice dynamics\" refers to advection of sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/snowfall_amount.json b/data_descriptors/standard_name/snowfall_amount.json index 7312ec007..3a6e177ea 100644 --- a/data_descriptors/standard_name/snowfall_amount.json +++ b/data_descriptors/standard_name/snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/snowfall_amount", + "id": "snowfall_amount", "type": "standard_name", "name": "snowfall_amount", "description": "\"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/snowfall_flux.json b/data_descriptors/standard_name/snowfall_flux.json index 07f113b39..6d1c1539f 100644 --- a/data_descriptors/standard_name/snowfall_flux.json +++ b/data_descriptors/standard_name/snowfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/snowfall_flux", + "id": "snowfall_flux", "type": "standard_name", "name": "snowfall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/soil_albedo.json b/data_descriptors/standard_name/soil_albedo.json index 6925a5ae2..48b456589 100644 --- a/data_descriptors/standard_name/soil_albedo.json +++ b/data_descriptors/standard_name/soil_albedo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_albedo", + "id": "soil_albedo", "type": "standard_name", "name": "soil_albedo", "description": "Soil albedo is the albedo of the soil surface assuming no snow. Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum.", diff --git a/data_descriptors/standard_name/soil_density.json b/data_descriptors/standard_name/soil_density.json index ed4864b4e..a2e3fdc39 100644 --- a/data_descriptors/standard_name/soil_density.json +++ b/data_descriptors/standard_name/soil_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_density", + "id": "soil_density", "type": "standard_name", "name": "soil_density", "description": "The density of the soil in its natural condition. Also known as bulk density. The density of a substance is its mass per unit volume.", diff --git a/data_descriptors/standard_name/soil_frozen_water_content.json b/data_descriptors/standard_name/soil_frozen_water_content.json index c3ac3e1b8..02a292cf0 100644 --- a/data_descriptors/standard_name/soil_frozen_water_content.json +++ b/data_descriptors/standard_name/soil_frozen_water_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_frozen_water_content", + "id": "soil_frozen_water_content", "type": "standard_name", "name": "soil_frozen_water_content", "description": "\"frozen_water\" means ice. \"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used.", diff --git a/data_descriptors/standard_name/soil_hydraulic_conductivity_at_saturation.json b/data_descriptors/standard_name/soil_hydraulic_conductivity_at_saturation.json index ae1982cd4..d9d6b86fb 100644 --- a/data_descriptors/standard_name/soil_hydraulic_conductivity_at_saturation.json +++ b/data_descriptors/standard_name/soil_hydraulic_conductivity_at_saturation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_hydraulic_conductivity_at_saturation", + "id": "soil_hydraulic_conductivity_at_saturation", "type": "standard_name", "name": "soil_hydraulic_conductivity_at_saturation", "description": "Hydraulic conductivity is the constant k in Darcy's Law q=-k grad h for fluid flow q (volume transport per unit area i.e. velocity) through a porous medium, where h is the hydraulic head (pressure expressed as an equivalent depth of water).", diff --git a/data_descriptors/standard_name/soil_liquid_water_content.json b/data_descriptors/standard_name/soil_liquid_water_content.json index 8c2f57aca..4ef572ca7 100644 --- a/data_descriptors/standard_name/soil_liquid_water_content.json +++ b/data_descriptors/standard_name/soil_liquid_water_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_liquid_water_content", + "id": "soil_liquid_water_content", "type": "standard_name", "name": "soil_liquid_water_content", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_13C.json b/data_descriptors/standard_name/soil_mass_content_of_13C.json index 872a74b09..132771c92 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_13C.json +++ b/data_descriptors/standard_name/soil_mass_content_of_13C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_13C", + "id": "soil_mass_content_of_13C", "type": "standard_name", "name": "soil_mass_content_of_13C", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_14C.json b/data_descriptors/standard_name/soil_mass_content_of_14C.json index 918331a51..c5219ec06 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_14C.json +++ b/data_descriptors/standard_name/soil_mass_content_of_14C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_14C", + "id": "soil_mass_content_of_14C", "type": "standard_name", "name": "soil_mass_content_of_14C", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_carbon.json b/data_descriptors/standard_name/soil_mass_content_of_carbon.json index 08316f0f8..b19b0cb84 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/soil_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_carbon", + "id": "soil_mass_content_of_carbon", "type": "standard_name", "name": "soil_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen.json b/data_descriptors/standard_name/soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen.json index 448934a2a..7afd9c935 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen", + "id": "soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen", "type": "standard_name", "name": "soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for the ammonium cation is NH4+. The quantity with standard name soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen is the sum of the quantities with standard names soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen and soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.json b/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.json index 8024e6298..e9213788a 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen", + "id": "soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen", "type": "standard_name", "name": "soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. The chemical formula for the nitrate anion is NO3-. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The quantity with standard name soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen is the sum of the quantities with standard names soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen and soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen.json b/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen.json index d8e6b3061..d33d80897 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen", + "id": "soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen", "type": "standard_name", "name": "soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Inorganic nitrogen\" describes a family of chemical species which, in soil, usually consists of nitrate and ammonium which act as nitrogen nutrients. The quantity with standard name soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen is the sum of the quantities with standard names soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen and soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen.", diff --git a/data_descriptors/standard_name/soil_mass_content_of_nitrogen.json b/data_descriptors/standard_name/soil_mass_content_of_nitrogen.json index 2735e0d6c..0730a0261 100644 --- a/data_descriptors/standard_name/soil_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/soil_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_mass_content_of_nitrogen", + "id": "soil_mass_content_of_nitrogen", "type": "standard_name", "name": "soil_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used.", diff --git a/data_descriptors/standard_name/soil_moisture_content_at_field_capacity.json b/data_descriptors/standard_name/soil_moisture_content_at_field_capacity.json index fbce72bbb..f29416eee 100644 --- a/data_descriptors/standard_name/soil_moisture_content_at_field_capacity.json +++ b/data_descriptors/standard_name/soil_moisture_content_at_field_capacity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_moisture_content_at_field_capacity", + "id": "soil_moisture_content_at_field_capacity", "type": "standard_name", "name": "soil_moisture_content_at_field_capacity", "description": "\"moisture\" means water in all phases contained in soil. \"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used. The field capacity of soil is the maximum content of water it can retain against gravitational drainage.", diff --git a/data_descriptors/standard_name/soil_pool.json b/data_descriptors/standard_name/soil_pool.json index 01acb774e..f27976421 100644 --- a/data_descriptors/standard_name/soil_pool.json +++ b/data_descriptors/standard_name/soil_pool.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_pool", + "id": "soil_pool", "type": "standard_name", "name": "soil_pool", "description": "A variable with the standard name of soil_pool contains strings which indicate the character of the soil pool classified according to the decay rate of the organic carbon material it contains. These strings have not yet been standardised.", diff --git a/data_descriptors/standard_name/soil_pool_carbon_decay_rate.json b/data_descriptors/standard_name/soil_pool_carbon_decay_rate.json index 685ec25eb..ad1cd1e9f 100644 --- a/data_descriptors/standard_name/soil_pool_carbon_decay_rate.json +++ b/data_descriptors/standard_name/soil_pool_carbon_decay_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_pool_carbon_decay_rate", + "id": "soil_pool_carbon_decay_rate", "type": "standard_name", "name": "soil_pool_carbon_decay_rate", "description": "\"Soil carbon\" is the organic matter present in soil quantified by the mass of carbon it contains. Soil carbon is returned to the atmosphere as the organic matter decays. Each modelled soil carbon pool has a characteristic turnover time, which is modified by environmental conditions such as temperature and moisture so that the turnover time varies in space and time. The quantity with standard name soil_pool_carbon_decay_rate is defined as 1/(turnover time). The data variable should be accompanied by a string valued coordinate variable or scalar coordinate variable with standard name soil_pool.", diff --git a/data_descriptors/standard_name/soil_porosity.json b/data_descriptors/standard_name/soil_porosity.json index ba99514cf..7c2c71ca2 100644 --- a/data_descriptors/standard_name/soil_porosity.json +++ b/data_descriptors/standard_name/soil_porosity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_porosity", + "id": "soil_porosity", "type": "standard_name", "name": "soil_porosity", "description": "The soil porosity is the proportion of its total volume not occupied by soil solids.", diff --git a/data_descriptors/standard_name/soil_suction_at_saturation.json b/data_descriptors/standard_name/soil_suction_at_saturation.json index 7f700213d..7e6c9eeaa 100644 --- a/data_descriptors/standard_name/soil_suction_at_saturation.json +++ b/data_descriptors/standard_name/soil_suction_at_saturation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_suction_at_saturation", + "id": "soil_suction_at_saturation", "type": "standard_name", "name": "soil_suction_at_saturation", "description": "Soil suction is the tensile stress on water in soil due to molecular forces acting at the water-soil particle boundary. The forces may cause water to be drawn into the spaces within the soil matrix or cause it to be held in the soil without draining. Soil suction occurs in soil above the water table.", diff --git a/data_descriptors/standard_name/soil_temperature.json b/data_descriptors/standard_name/soil_temperature.json index 7d006143d..129aa66a6 100644 --- a/data_descriptors/standard_name/soil_temperature.json +++ b/data_descriptors/standard_name/soil_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_temperature", + "id": "soil_temperature", "type": "standard_name", "name": "soil_temperature", "description": "Soil temperature is the bulk temperature of the soil, not the surface (skin) temperature. \"Soil\" means the near-surface layer where plants sink their roots. For subsurface temperatures that extend beneath the soil layer or in areas where there is no surface soil layer, the standard name temperature_in_ground should be used. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/soil_thermal_capacity.json b/data_descriptors/standard_name/soil_thermal_capacity.json index 3219a0464..b11e73895 100644 --- a/data_descriptors/standard_name/soil_thermal_capacity.json +++ b/data_descriptors/standard_name/soil_thermal_capacity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_thermal_capacity", + "id": "soil_thermal_capacity", "type": "standard_name", "name": "soil_thermal_capacity", "description": "Thermal capacity, or heat capacity, is the amount of heat energy required to increase the temperature of 1 kg of material by 1 K. It is a property of the material. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/soil_thermal_conductivity.json b/data_descriptors/standard_name/soil_thermal_conductivity.json index 107a38c6e..68d06de0f 100644 --- a/data_descriptors/standard_name/soil_thermal_conductivity.json +++ b/data_descriptors/standard_name/soil_thermal_conductivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_thermal_conductivity", + "id": "soil_thermal_conductivity", "type": "standard_name", "name": "soil_thermal_conductivity", "description": "Thermal conductivity is the constant k in the formula q = -k grad T where q is the heat transfer per unit time per unit area of a surface normal to the direction of transfer and grad T is the temperature gradient. Thermal conductivity is a property of the material. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/soil_type.json b/data_descriptors/standard_name/soil_type.json index d59e5aee5..1bba47567 100644 --- a/data_descriptors/standard_name/soil_type.json +++ b/data_descriptors/standard_name/soil_type.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_type", + "id": "soil_type", "type": "standard_name", "name": "soil_type", "description": "A variable with the standard name of soil_type contains strings which indicate the character of the soil e.g. clay. These strings have not yet been standardised. Alternatively, the data variable may contain integers which can be translated to strings using flag_values and flag_meanings attributes.", diff --git a/data_descriptors/standard_name/soil_water_ph.json b/data_descriptors/standard_name/soil_water_ph.json index 7fcea252c..41a65f1b9 100644 --- a/data_descriptors/standard_name/soil_water_ph.json +++ b/data_descriptors/standard_name/soil_water_ph.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_water_ph", + "id": "soil_water_ph", "type": "standard_name", "name": "soil_water_ph", "description": "soil_water_ph is the measure of acidity of soil moisture, defined as the negative logarithm of the concentration of dissolved hydrogen ions in soil water.", diff --git a/data_descriptors/standard_name/soil_water_salinity.json b/data_descriptors/standard_name/soil_water_salinity.json index 322324a71..f9eb1a50c 100644 --- a/data_descriptors/standard_name/soil_water_salinity.json +++ b/data_descriptors/standard_name/soil_water_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soil_water_salinity", + "id": "soil_water_salinity", "type": "standard_name", "name": "soil_water_salinity", "description": "The quantity with standard name soil_water_salinity is the salt content of soil water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand.", diff --git a/data_descriptors/standard_name/solar_azimuth_angle.json b/data_descriptors/standard_name/solar_azimuth_angle.json index 4f306279d..8b41502d6 100644 --- a/data_descriptors/standard_name/solar_azimuth_angle.json +++ b/data_descriptors/standard_name/solar_azimuth_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solar_azimuth_angle", + "id": "solar_azimuth_angle", "type": "standard_name", "name": "solar_azimuth_angle", "description": "Solar azimuth angle is the horizontal angle between the line of sight to the sun and a reference direction which is often due north. The angle is measured clockwise.", diff --git a/data_descriptors/standard_name/solar_elevation_angle.json b/data_descriptors/standard_name/solar_elevation_angle.json index 036122df2..5d49dae4c 100644 --- a/data_descriptors/standard_name/solar_elevation_angle.json +++ b/data_descriptors/standard_name/solar_elevation_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solar_elevation_angle", + "id": "solar_elevation_angle", "type": "standard_name", "name": "solar_elevation_angle", "description": "Solar elevation angle is the angle between the line of sight to the sun and the local horizontal.", diff --git a/data_descriptors/standard_name/solar_irradiance.json b/data_descriptors/standard_name/solar_irradiance.json index c260894f1..c0476ee49 100644 --- a/data_descriptors/standard_name/solar_irradiance.json +++ b/data_descriptors/standard_name/solar_irradiance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solar_irradiance", + "id": "solar_irradiance", "type": "standard_name", "name": "solar_irradiance", "description": "The quantity with standard name solar_irradiance, often called Total Solar Irradiance (TSI), is the radiation from the sun integrated over the whole electromagnetic spectrum and over the entire solar disk. The quantity applies outside the atmosphere, by default at a distance of one astronomical unit from the sun, but a coordinate or scalar coordinate variable of distance_from_sun can be used to specify a value other than the default. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy.", diff --git a/data_descriptors/standard_name/solar_irradiance_per_unit_wavelength.json b/data_descriptors/standard_name/solar_irradiance_per_unit_wavelength.json index 37e971a82..c12385997 100644 --- a/data_descriptors/standard_name/solar_irradiance_per_unit_wavelength.json +++ b/data_descriptors/standard_name/solar_irradiance_per_unit_wavelength.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solar_irradiance_per_unit_wavelength", + "id": "solar_irradiance_per_unit_wavelength", "type": "standard_name", "name": "solar_irradiance_per_unit_wavelength", "description": "The quantity with standard name solar_irradiance_per_unit_wavelength, often called Solar Spectral Irradiance (SSI), is the radiation from the sun as a function of wavelength integrated over the entire solar disk. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength. The quantity applies outside the atmosphere, by default at a distance of one astronomical unit from the sun, but a coordinate or scalar coordinate variable of distance_from_sun can be used to specify a value other than the default. \"Irradiance\" means the power per unit area (called radiative flux in other standard names), the area being normal to the direction of flow of the radiant energy.", diff --git a/data_descriptors/standard_name/solar_zenith_angle.json b/data_descriptors/standard_name/solar_zenith_angle.json index e761b7436..01842a349 100644 --- a/data_descriptors/standard_name/solar_zenith_angle.json +++ b/data_descriptors/standard_name/solar_zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solar_zenith_angle", + "id": "solar_zenith_angle", "type": "standard_name", "name": "solar_zenith_angle", "description": "Solar zenith angle is the the angle between the line of sight to the sun and the local vertical.", diff --git a/data_descriptors/standard_name/solid_precipitation_flux.json b/data_descriptors/standard_name/solid_precipitation_flux.json index d5acb7d25..859d74579 100644 --- a/data_descriptors/standard_name/solid_precipitation_flux.json +++ b/data_descriptors/standard_name/solid_precipitation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solid_precipitation_flux", + "id": "solid_precipitation_flux", "type": "standard_name", "name": "solid_precipitation_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Solid precipitation refers to the precipitation of water in the solid phase. Water in the atmosphere exists in one of three phases: solid, liquid or vapor. The solid phase can exist as snow, hail, graupel, cloud ice, or as a component of aerosol.", diff --git a/data_descriptors/standard_name/solid_precipitation_flux_containing_17O.json b/data_descriptors/standard_name/solid_precipitation_flux_containing_17O.json index 9ddc02d81..a1e8bc6e1 100644 --- a/data_descriptors/standard_name/solid_precipitation_flux_containing_17O.json +++ b/data_descriptors/standard_name/solid_precipitation_flux_containing_17O.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solid_precipitation_flux_containing_17O", + "id": "solid_precipitation_flux_containing_17O", "type": "standard_name", "name": "solid_precipitation_flux_containing_17O", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Solid precipitation refers to the precipitation of water in the solid phase. Water in the atmosphere exists in one of three phases: solid, liquid or vapor. The solid phase can exist as snow, hail, graupel, cloud ice, or as a component of aerosol. \"O\" means the element \"oxygen\" and \"17O\" is the stable isotope \"oxygen-17\".", diff --git a/data_descriptors/standard_name/solid_precipitation_flux_containing_18O.json b/data_descriptors/standard_name/solid_precipitation_flux_containing_18O.json index c805abaee..1d328a3c9 100644 --- a/data_descriptors/standard_name/solid_precipitation_flux_containing_18O.json +++ b/data_descriptors/standard_name/solid_precipitation_flux_containing_18O.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solid_precipitation_flux_containing_18O", + "id": "solid_precipitation_flux_containing_18O", "type": "standard_name", "name": "solid_precipitation_flux_containing_18O", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Solid precipitation refers to the precipitation of water in the solid phase. Water in the atmosphere exists in one of three phases: solid, liquid or vapor. The solid phase can exist as snow, hail, graupel, cloud ice, or as a component of aerosol. The chemical formula for water is H2O. \"O\" means the element \"oxygen\" and \"18O\" is the stable isotope \"oxygen-18\".", diff --git a/data_descriptors/standard_name/solid_precipitation_flux_containing_single_2H.json b/data_descriptors/standard_name/solid_precipitation_flux_containing_single_2H.json index 1fd60491c..4ffe2cbcb 100644 --- a/data_descriptors/standard_name/solid_precipitation_flux_containing_single_2H.json +++ b/data_descriptors/standard_name/solid_precipitation_flux_containing_single_2H.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/solid_precipitation_flux_containing_single_2H", + "id": "solid_precipitation_flux_containing_single_2H", "type": "standard_name", "name": "solid_precipitation_flux_containing_single_2H", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Solid precipitation refers to the precipitation of water in the solid phase. Water in the atmosphere exists in one of three phases: solid, liquid or vapor. The solid phase can exist as snow, hail, graupel, cloud ice, or as a component of aerosol. The chemical formula for water is H2O. \"H\" means the element \"hydrogen\" and \"2H\" is the stable isotope \"hydrogen-2\", usually called \"deuterium\". The construction \"X_containing_single_Y\" means the standard name refers to only that part of X composed of molecules containing a single atom of isotope Y.", diff --git a/data_descriptors/standard_name/soot_content_of_surface_snow.json b/data_descriptors/standard_name/soot_content_of_surface_snow.json index fde6b1d70..7fe1adb82 100644 --- a/data_descriptors/standard_name/soot_content_of_surface_snow.json +++ b/data_descriptors/standard_name/soot_content_of_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/soot_content_of_surface_snow", + "id": "soot_content_of_surface_snow", "type": "standard_name", "name": "soot_content_of_surface_snow", "description": "\"Content\" indicates a quantity per unit area. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/sound_frequency.json b/data_descriptors/standard_name/sound_frequency.json index ab30b271e..88c80ce49 100644 --- a/data_descriptors/standard_name/sound_frequency.json +++ b/data_descriptors/standard_name/sound_frequency.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_frequency", + "id": "sound_frequency", "type": "standard_name", "name": "sound_frequency", "description": "Frequency is the number of oscillations of a wave per unit time.", diff --git a/data_descriptors/standard_name/sound_intensity_in_air.json b/data_descriptors/standard_name/sound_intensity_in_air.json index 5c5723859..8baed48f0 100644 --- a/data_descriptors/standard_name/sound_intensity_in_air.json +++ b/data_descriptors/standard_name/sound_intensity_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_intensity_in_air", + "id": "sound_intensity_in_air", "type": "standard_name", "name": "sound_intensity_in_air", "description": "Sound intensity is the sound energy per unit time per unit area.", diff --git a/data_descriptors/standard_name/sound_intensity_in_water.json b/data_descriptors/standard_name/sound_intensity_in_water.json index bb3cbe920..44b358bb3 100644 --- a/data_descriptors/standard_name/sound_intensity_in_water.json +++ b/data_descriptors/standard_name/sound_intensity_in_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_intensity_in_water", + "id": "sound_intensity_in_water", "type": "standard_name", "name": "sound_intensity_in_water", "description": "Sound intensity is the sound energy per unit time per unit area.", diff --git a/data_descriptors/standard_name/sound_intensity_level_in_air.json b/data_descriptors/standard_name/sound_intensity_level_in_air.json index acf56a9d1..6dbed67a0 100644 --- a/data_descriptors/standard_name/sound_intensity_level_in_air.json +++ b/data_descriptors/standard_name/sound_intensity_level_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_intensity_level_in_air", + "id": "sound_intensity_level_in_air", "type": "standard_name", "name": "sound_intensity_level_in_air", "description": "Sound intensity is the sound energy per unit time per unit area. Sound intensity level in air is expressed on a logarithmic scale with reference to a sound intensity of 1e-12 W m-2. LI = 10 log10(I/I0) where LI is sound intensity level, I is sound intensity and I0 is the reference sound intensity.", diff --git a/data_descriptors/standard_name/sound_intensity_level_in_water.json b/data_descriptors/standard_name/sound_intensity_level_in_water.json index 8dd059972..d82b9fc08 100644 --- a/data_descriptors/standard_name/sound_intensity_level_in_water.json +++ b/data_descriptors/standard_name/sound_intensity_level_in_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_intensity_level_in_water", + "id": "sound_intensity_level_in_water", "type": "standard_name", "name": "sound_intensity_level_in_water", "description": "Sound intensity is the sound energy per unit time per unit area. Sound intensity level in water is expressed on a logarithmic scale with reference to a sound intensity of 6.7e-19 W m-2. LI = 10 log10(I/I0) where LI is sound intensity level, I is sound intensity and I0 is the reference sound intensity.", diff --git a/data_descriptors/standard_name/sound_pressure_in_air.json b/data_descriptors/standard_name/sound_pressure_in_air.json index 6d0238ca5..54fef636d 100644 --- a/data_descriptors/standard_name/sound_pressure_in_air.json +++ b/data_descriptors/standard_name/sound_pressure_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_pressure_in_air", + "id": "sound_pressure_in_air", "type": "standard_name", "name": "sound_pressure_in_air", "description": "Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time.", diff --git a/data_descriptors/standard_name/sound_pressure_in_water.json b/data_descriptors/standard_name/sound_pressure_in_water.json index f14d01bbd..da45ac35b 100644 --- a/data_descriptors/standard_name/sound_pressure_in_water.json +++ b/data_descriptors/standard_name/sound_pressure_in_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_pressure_in_water", + "id": "sound_pressure_in_water", "type": "standard_name", "name": "sound_pressure_in_water", "description": "Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time.", diff --git a/data_descriptors/standard_name/sound_pressure_level_in_air.json b/data_descriptors/standard_name/sound_pressure_level_in_air.json index a1ba17008..3206f42ba 100644 --- a/data_descriptors/standard_name/sound_pressure_level_in_air.json +++ b/data_descriptors/standard_name/sound_pressure_level_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_pressure_level_in_air", + "id": "sound_pressure_level_in_air", "type": "standard_name", "name": "sound_pressure_level_in_air", "description": "Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time. Sound pressure level in air is expressed on a logarithmic scale with reference to a sound pressure of 2e-5 Pa. Lp = 20 log10(p/p0) where Lp is the sound pressure level, p is the rms sound pressure and p0 is the reference sound pressure.", diff --git a/data_descriptors/standard_name/sound_pressure_level_in_water.json b/data_descriptors/standard_name/sound_pressure_level_in_water.json index 37983b316..e95e4467a 100644 --- a/data_descriptors/standard_name/sound_pressure_level_in_water.json +++ b/data_descriptors/standard_name/sound_pressure_level_in_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sound_pressure_level_in_water", + "id": "sound_pressure_level_in_water", "type": "standard_name", "name": "sound_pressure_level_in_water", "description": "Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time. Sound pressure level in water is expressed on a logarithmic scale with reference to a sound pressure of 1e-6 Pa. Lp = 20 log10(p/p0) where Lp is the sound pressure level, p is the rms sound pressure and p0 is the reference sound pressure.", diff --git a/data_descriptors/standard_name/source.json b/data_descriptors/standard_name/source.json index 3f257b99b..39d68a78c 100644 --- a/data_descriptors/standard_name/source.json +++ b/data_descriptors/standard_name/source.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/source", + "id": "source", "type": "standard_name", "name": "source", "description": "An auxiliary coordinate variable with a standard name of source contains string values which describe the method of production of the original data with which the coordinate variable is associated. If the data were model-generated, source should name the model and its version, as specifically as could be useful. If the data are observational, source should characterize them (e.g., \"surface observation\", \"radiosonde\"). The use of source as the standard name for an auxiliary coordinate variable permits the aggregation of data from multiple sources within a single data file.", diff --git a/data_descriptors/standard_name/specific_dry_energy_of_air.json b/data_descriptors/standard_name/specific_dry_energy_of_air.json index 283920e24..175fc36b8 100644 --- a/data_descriptors/standard_name/specific_dry_energy_of_air.json +++ b/data_descriptors/standard_name/specific_dry_energy_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_dry_energy_of_air", + "id": "specific_dry_energy_of_air", "type": "standard_name", "name": "specific_dry_energy_of_air", "description": "\"specific\" means per unit mass. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/specific_enthalpy_of_air.json b/data_descriptors/standard_name/specific_enthalpy_of_air.json index 647a3d499..d23ae3f83 100644 --- a/data_descriptors/standard_name/specific_enthalpy_of_air.json +++ b/data_descriptors/standard_name/specific_enthalpy_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_enthalpy_of_air", + "id": "specific_enthalpy_of_air", "type": "standard_name", "name": "specific_enthalpy_of_air", "description": "The specific_enthalpy_of_air is the enthalpy of air per unit mass, which can be computed for an air sample as the sum of the enthalpy of the dry air and the enthalpy of the water vapor in that air, divided by the mass of dry air.", diff --git a/data_descriptors/standard_name/specific_gravitational_potential_energy.json b/data_descriptors/standard_name/specific_gravitational_potential_energy.json index 65111f0e0..446e7d4dd 100644 --- a/data_descriptors/standard_name/specific_gravitational_potential_energy.json +++ b/data_descriptors/standard_name/specific_gravitational_potential_energy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_gravitational_potential_energy", + "id": "specific_gravitational_potential_energy", "type": "standard_name", "name": "specific_gravitational_potential_energy", "description": "\"specific\" means per unit mass. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/specific_heat_capacity_of_frozen_ground.json b/data_descriptors/standard_name/specific_heat_capacity_of_frozen_ground.json index 29da3bd0b..ca5823164 100644 --- a/data_descriptors/standard_name/specific_heat_capacity_of_frozen_ground.json +++ b/data_descriptors/standard_name/specific_heat_capacity_of_frozen_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_heat_capacity_of_frozen_ground", + "id": "specific_heat_capacity_of_frozen_ground", "type": "standard_name", "name": "specific_heat_capacity_of_frozen_ground", "description": "Thermal capacity, or heat capacity, is the amount of heat energy required to increase the temperature of 1 kg of material by 1 K. It is a property of the material. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/specific_heat_capacity_of_sea_water.json b/data_descriptors/standard_name/specific_heat_capacity_of_sea_water.json index df4db8741..6874234c0 100644 --- a/data_descriptors/standard_name/specific_heat_capacity_of_sea_water.json +++ b/data_descriptors/standard_name/specific_heat_capacity_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_heat_capacity_of_sea_water", + "id": "specific_heat_capacity_of_sea_water", "type": "standard_name", "name": "specific_heat_capacity_of_sea_water", "description": "The specific heat capacity of sea water, Cp(ocean), is used in ocean models to convert between model prognostic temperature (potential or conservative temperature) and model heat content. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/specific_humidity.json b/data_descriptors/standard_name/specific_humidity.json index e664a2f90..013f43327 100644 --- a/data_descriptors/standard_name/specific_humidity.json +++ b/data_descriptors/standard_name/specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_humidity", + "id": "specific_humidity", "type": "standard_name", "name": "specific_humidity", "description": "\"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/specific_kinetic_energy_of_air.json b/data_descriptors/standard_name/specific_kinetic_energy_of_air.json index 0db863d17..b59699d93 100644 --- a/data_descriptors/standard_name/specific_kinetic_energy_of_air.json +++ b/data_descriptors/standard_name/specific_kinetic_energy_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_kinetic_energy_of_air", + "id": "specific_kinetic_energy_of_air", "type": "standard_name", "name": "specific_kinetic_energy_of_air", "description": "\"specific\" means per unit mass.", diff --git a/data_descriptors/standard_name/specific_kinetic_energy_of_sea_water.json b/data_descriptors/standard_name/specific_kinetic_energy_of_sea_water.json index 590385ec3..d28be529d 100644 --- a/data_descriptors/standard_name/specific_kinetic_energy_of_sea_water.json +++ b/data_descriptors/standard_name/specific_kinetic_energy_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_kinetic_energy_of_sea_water", + "id": "specific_kinetic_energy_of_sea_water", "type": "standard_name", "name": "specific_kinetic_energy_of_sea_water", "description": "\"specific\" means per unit mass.", diff --git a/data_descriptors/standard_name/specific_turbulent_kinetic_energy_dissipation_in_sea_water.json b/data_descriptors/standard_name/specific_turbulent_kinetic_energy_dissipation_in_sea_water.json index 1600b83b7..86a4e1477 100644 --- a/data_descriptors/standard_name/specific_turbulent_kinetic_energy_dissipation_in_sea_water.json +++ b/data_descriptors/standard_name/specific_turbulent_kinetic_energy_dissipation_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_turbulent_kinetic_energy_dissipation_in_sea_water", + "id": "specific_turbulent_kinetic_energy_dissipation_in_sea_water", "type": "standard_name", "name": "specific_turbulent_kinetic_energy_dissipation_in_sea_water", "description": "\"Specific\" means per unit mass. \"Turbulent kinetic energy\" is the kinetic energy of chaotic fluctuations of the fluid flow. The dissipation of kinetic energy arises in ocean models as a result of the viscosity of sea water.", diff --git a/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_air.json b/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_air.json index a5f025b68..774167786 100644 --- a/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_air.json +++ b/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_turbulent_kinetic_energy_of_air", + "id": "specific_turbulent_kinetic_energy_of_air", "type": "standard_name", "name": "specific_turbulent_kinetic_energy_of_air", "description": "Specific means per unit mass. \"Turbulent kinetic energy\" is the kinetic energy of all eddy-induced motion that is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_sea_water.json b/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_sea_water.json index 1e7a1a88c..080f2a54b 100644 --- a/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_sea_water.json +++ b/data_descriptors/standard_name/specific_turbulent_kinetic_energy_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/specific_turbulent_kinetic_energy_of_sea_water", + "id": "specific_turbulent_kinetic_energy_of_sea_water", "type": "standard_name", "name": "specific_turbulent_kinetic_energy_of_sea_water", "description": "\"Specific\" means per unit mass. \"Turbulent kinetic energy\" is the kinetic energy of chaotic fluctuations of the fluid flow.", diff --git a/data_descriptors/standard_name/spectral_width_of_radio_wave_in_air_scattered_by_air.json b/data_descriptors/standard_name/spectral_width_of_radio_wave_in_air_scattered_by_air.json index 5a6c9e0fb..e7672be67 100644 --- a/data_descriptors/standard_name/spectral_width_of_radio_wave_in_air_scattered_by_air.json +++ b/data_descriptors/standard_name/spectral_width_of_radio_wave_in_air_scattered_by_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spectral_width_of_radio_wave_in_air_scattered_by_air", + "id": "spectral_width_of_radio_wave_in_air_scattered_by_air", "type": "standard_name", "name": "spectral_width_of_radio_wave_in_air_scattered_by_air", "description": "Frequency width of the radio wave, that was transmitted by an instrument and propagates in the air where it's scattered by the air due to which its properties change, and it is received by an instrument. The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities in the air). A standard name referring to frequency spectra width of the signal received at the instrument.", diff --git a/data_descriptors/standard_name/spectral_width_of_radio_wave_scattered_by_air.json b/data_descriptors/standard_name/spectral_width_of_radio_wave_scattered_by_air.json index d30e5af37..07e20c92a 100644 --- a/data_descriptors/standard_name/spectral_width_of_radio_wave_scattered_by_air.json +++ b/data_descriptors/standard_name/spectral_width_of_radio_wave_scattered_by_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spectral_width_of_radio_wave_scattered_by_air", + "id": "spectral_width_of_radio_wave_scattered_by_air", "type": "standard_name", "name": "spectral_width_of_radio_wave_scattered_by_air", "description": "The \"instrument\" (examples are radar and lidar) is the device used to make the observation. The \"scatterers\" are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities), of whatever kind the instrument detects. A standard name referring to frequency width of the received signal.", diff --git a/data_descriptors/standard_name/speed_of_sound_in_air.json b/data_descriptors/standard_name/speed_of_sound_in_air.json index 4060df38b..6c020ebe7 100644 --- a/data_descriptors/standard_name/speed_of_sound_in_air.json +++ b/data_descriptors/standard_name/speed_of_sound_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/speed_of_sound_in_air", + "id": "speed_of_sound_in_air", "type": "standard_name", "name": "speed_of_sound_in_air", "description": "Speed is the magnitude of velocity.", diff --git a/data_descriptors/standard_name/speed_of_sound_in_sea_water.json b/data_descriptors/standard_name/speed_of_sound_in_sea_water.json index fc3a31992..522226fd0 100644 --- a/data_descriptors/standard_name/speed_of_sound_in_sea_water.json +++ b/data_descriptors/standard_name/speed_of_sound_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/speed_of_sound_in_sea_water", + "id": "speed_of_sound_in_sea_water", "type": "standard_name", "name": "speed_of_sound_in_sea_water", "description": "Speed is the magnitude of velocity.", diff --git a/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_above_threshold.json b/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_above_threshold.json index cb60d45a4..527415c35 100644 --- a/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_above_threshold.json +++ b/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spell_length_of_days_with_air_temperature_above_threshold", + "id": "spell_length_of_days_with_air_temperature_above_threshold", "type": "standard_name", "name": "spell_length_of_days_with_air_temperature_above_threshold", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A spell is the number of consecutive days on which the condition X_below|above_threshold is satisfied. A variable whose standard name has the form spell_length_of_days_with_X_below|above_threshold must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_method entry for within days which describes the processing of quantity X before the threshold is applied. A spell_length_of_days is an intensive quantity in time, and the cell_methods entry for over days can be any of the methods listed in Appendix E appropriate for intensive quantities e.g. \"maximum\", \"minimum\" or \"mean\".", diff --git a/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_below_threshold.json b/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_below_threshold.json index d3953031f..04b26f477 100644 --- a/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_below_threshold.json +++ b/data_descriptors/standard_name/spell_length_of_days_with_air_temperature_below_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spell_length_of_days_with_air_temperature_below_threshold", + "id": "spell_length_of_days_with_air_temperature_below_threshold", "type": "standard_name", "name": "spell_length_of_days_with_air_temperature_below_threshold", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A spell is the number of consecutive days on which the condition X_below|above_threshold is satisfied. A variable whose standard name has the form spell_length_of_days_with_X_below|above_threshold must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_method entry for within days which describes the processing of quantity X before the threshold is applied. A spell_length_of_days is an intensive quantity in time, and the cell_methods entry for over days can be any of the methods listed in Appendix E appropriate for intensive quantities e.g. \"maximum\", \"minimum\" or \"mean\".", diff --git a/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json b/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json index 5a9a67b44..a6e1cc11a 100644 --- a/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json +++ b/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold", + "id": "spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold", "type": "standard_name", "name": "spell_length_of_days_with_lwe_thickness_of_precipitation_amount_above_threshold", "description": "\"Amount\" means mass per unit area. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. The abbreviation \"lwe\" means liquid water equivalent. A spell is the number of consecutive days on which the condition X_below|above_threshold is satisfied. A variable whose standard name has the form spell_length_of_days_with_X_below|above_threshold must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_method entry for within days which describes the processing of quantity X before the threshold is applied. A spell_length_of_days is an intensive quantity in time, and the cell_methods entry for over days can be any of the methods listed in Appendix E appropriate for intensive quantities e.g. \"maximum\", \"minimum\" or \"mean\".", diff --git a/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold.json b/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold.json index e1f2a3d02..c62419936 100644 --- a/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold.json +++ b/data_descriptors/standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold", + "id": "spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold", "type": "standard_name", "name": "spell_length_of_days_with_lwe_thickness_of_precipitation_amount_below_threshold", "description": "\"Amount\" means mass per unit area. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases.The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. The abbreviation \"lwe\" means liquid water equivalent. A spell is the number of consecutive days on which the condition X_below|above_threshold is satisfied. A variable whose standard name has the form spell_length_of_days_with_X_below|above_threshold must have a coordinate variable or scalar coordinate variable with the standard name of X to supply the threshold(s). It must have a climatological time variable, and a cell_method entry for within days which describes the processing of quantity X before the threshold is applied. A spell_length_of_days is an intensive quantity in time, and the cell_methods entry for over days can be any of the methods listed in Appendix E appropriate for intensive quantities e.g. \"maximum\", \"minimum\" or \"mean\".", diff --git a/data_descriptors/standard_name/spike_test_quality_flag.json b/data_descriptors/standard_name/spike_test_quality_flag.json index 2a2a05f1b..5c6cf515e 100644 --- a/data_descriptors/standard_name/spike_test_quality_flag.json +++ b/data_descriptors/standard_name/spike_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/spike_test_quality_flag", + "id": "spike_test_quality_flag", "type": "standard_name", "name": "spike_test_quality_flag", "description": "A quality flag that reports the result of the Spike test, which checks that the difference between two points in a series of values is within reasonable bounds. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/square_of_air_temperature.json b/data_descriptors/standard_name/square_of_air_temperature.json index 8cef1665d..397ab447a 100644 --- a/data_descriptors/standard_name/square_of_air_temperature.json +++ b/data_descriptors/standard_name/square_of_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_air_temperature", + "id": "square_of_air_temperature", "type": "standard_name", "name": "square_of_air_temperature", "description": "The phrase \"square_of_X\" means X*X. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_air.json b/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_air.json index 661999c24..1d1b367fb 100644 --- a/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_air.json +++ b/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_brunt_vaisala_frequency_in_air", + "id": "square_of_brunt_vaisala_frequency_in_air", "type": "standard_name", "name": "square_of_brunt_vaisala_frequency_in_air", "description": "The phrase \"square_of_X\" means X*X. Frequency is the number of oscillations of a wave per unit time. Brunt-Vaisala frequency is also sometimes called \"buoyancy frequency\" and is a measure of the vertical stratification of the medium.", diff --git a/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_sea_water.json b/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_sea_water.json index 532e554be..ee7f04187 100644 --- a/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_sea_water.json +++ b/data_descriptors/standard_name/square_of_brunt_vaisala_frequency_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_brunt_vaisala_frequency_in_sea_water", + "id": "square_of_brunt_vaisala_frequency_in_sea_water", "type": "standard_name", "name": "square_of_brunt_vaisala_frequency_in_sea_water", "description": "The phrase \"square_of_X\" means X*X. Frequency is the number of oscillations of a wave per unit time. Brunt-Vaisala frequency is also sometimes called \"buoyancy frequency\" and is a measure of the vertical stratification of the medium.", diff --git a/data_descriptors/standard_name/square_of_eastward_wind.json b/data_descriptors/standard_name/square_of_eastward_wind.json index b640ac5e1..afccf0338 100644 --- a/data_descriptors/standard_name/square_of_eastward_wind.json +++ b/data_descriptors/standard_name/square_of_eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_eastward_wind", + "id": "square_of_eastward_wind", "type": "standard_name", "name": "square_of_eastward_wind", "description": "\"square_of_X\" means X*X. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/square_of_geopotential_height.json b/data_descriptors/standard_name/square_of_geopotential_height.json index 696a1c3dc..e4bee6083 100644 --- a/data_descriptors/standard_name/square_of_geopotential_height.json +++ b/data_descriptors/standard_name/square_of_geopotential_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_geopotential_height", + "id": "square_of_geopotential_height", "type": "standard_name", "name": "square_of_geopotential_height", "description": "\"square_of_X\" means X*X. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", diff --git a/data_descriptors/standard_name/square_of_lagrangian_tendency_of_air_pressure.json b/data_descriptors/standard_name/square_of_lagrangian_tendency_of_air_pressure.json index dd7bb4e6e..6e0b0293e 100644 --- a/data_descriptors/standard_name/square_of_lagrangian_tendency_of_air_pressure.json +++ b/data_descriptors/standard_name/square_of_lagrangian_tendency_of_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_lagrangian_tendency_of_air_pressure", + "id": "square_of_lagrangian_tendency_of_air_pressure", "type": "standard_name", "name": "square_of_lagrangian_tendency_of_air_pressure", "description": "The phrase \"square_of_X\" means X*X. \"tendency_of_X\" means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the \"material derivative\" or \"convective derivative\". The Lagrangian tendency of air pressure, often called \"omega\", plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/square_of_northward_wind.json b/data_descriptors/standard_name/square_of_northward_wind.json index 126184263..9e776d535 100644 --- a/data_descriptors/standard_name/square_of_northward_wind.json +++ b/data_descriptors/standard_name/square_of_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_northward_wind", + "id": "square_of_northward_wind", "type": "standard_name", "name": "square_of_northward_wind", "description": "\"square_of_X\" means X*X. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/square_of_ocean_mixed_layer_thickness_defined_by_sigma_t.json b/data_descriptors/standard_name/square_of_ocean_mixed_layer_thickness_defined_by_sigma_t.json index 076519417..3ef5cb001 100644 --- a/data_descriptors/standard_name/square_of_ocean_mixed_layer_thickness_defined_by_sigma_t.json +++ b/data_descriptors/standard_name/square_of_ocean_mixed_layer_thickness_defined_by_sigma_t.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_ocean_mixed_layer_thickness_defined_by_sigma_t", + "id": "square_of_ocean_mixed_layer_thickness_defined_by_sigma_t", "type": "standard_name", "name": "square_of_ocean_mixed_layer_thickness_defined_by_sigma_t", "description": "The phrase \"square_of_X\" means X*X. The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by \"temperature\", \"sigma\", \"sigma_theta\", \"sigma_t\" or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_sigma_t_difference can be used to specify the sigma_t criterion that determines the layer thickness. Sigma-t of sea water is the density of water at atmospheric pressure (i.e. the surface) having the same temperature and salinity, minus 1000 kg m-3. \"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/square_of_sea_surface_height_above_geoid.json b/data_descriptors/standard_name/square_of_sea_surface_height_above_geoid.json index 0f4ec6695..eb7002977 100644 --- a/data_descriptors/standard_name/square_of_sea_surface_height_above_geoid.json +++ b/data_descriptors/standard_name/square_of_sea_surface_height_above_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_sea_surface_height_above_geoid", + "id": "square_of_sea_surface_height_above_geoid", "type": "standard_name", "name": "square_of_sea_surface_height_above_geoid", "description": "The phrase \"square_of_X\" means X*X. \"Height_above_X\" means the vertical distance above the named surface X. \"Sea surface height\" is a time-varying quantity. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention. By definition of the geoid, the global average of the time-mean sea surface height (i.e. mean sea level) above the geoid must be zero.", diff --git a/data_descriptors/standard_name/square_of_sea_surface_salinity.json b/data_descriptors/standard_name/square_of_sea_surface_salinity.json index 770a763bf..b4a9fcaac 100644 --- a/data_descriptors/standard_name/square_of_sea_surface_salinity.json +++ b/data_descriptors/standard_name/square_of_sea_surface_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_sea_surface_salinity", + "id": "square_of_sea_surface_salinity", "type": "standard_name", "name": "square_of_sea_surface_salinity", "description": "The phrase \"square_of_X\" means X*X. Sea surface salinity is the salt concentration of sea water close to the sea surface, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. Sea surface salinity is often abbreviated as \"SSS\". For the salinity of sea water at a particular depth or layer, a data variable of \"sea_water_salinity\" or one of the more precisely defined salinities should be used with a vertical coordinate axis. There are standard names for the precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/square_of_sea_surface_temperature.json b/data_descriptors/standard_name/square_of_sea_surface_temperature.json index f592b8e40..628994dec 100644 --- a/data_descriptors/standard_name/square_of_sea_surface_temperature.json +++ b/data_descriptors/standard_name/square_of_sea_surface_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_sea_surface_temperature", + "id": "square_of_sea_surface_temperature", "type": "standard_name", "name": "square_of_sea_surface_temperature", "description": "Sea surface temperature is usually abbreviated as \"SST\". It is the temperature of sea water near the surface (including the part under sea-ice, if any), and not the skin temperature, whose standard name is surface_temperature. For the temperature of sea water at a particular depth or layer, a data variable of sea_water_temperature with a vertical coordinate axis should be used. \"square_of_X\" means X*X. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/square_of_upward_air_velocity.json b/data_descriptors/standard_name/square_of_upward_air_velocity.json index a40bcc129..1418a5be5 100644 --- a/data_descriptors/standard_name/square_of_upward_air_velocity.json +++ b/data_descriptors/standard_name/square_of_upward_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_upward_air_velocity", + "id": "square_of_upward_air_velocity", "type": "standard_name", "name": "square_of_upward_air_velocity", "description": "\"square_of_X\" means X*X. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector.", diff --git a/data_descriptors/standard_name/square_of_upward_ocean_mass_transport.json b/data_descriptors/standard_name/square_of_upward_ocean_mass_transport.json index 70887d810..a2205e4e2 100644 --- a/data_descriptors/standard_name/square_of_upward_ocean_mass_transport.json +++ b/data_descriptors/standard_name/square_of_upward_ocean_mass_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/square_of_upward_ocean_mass_transport", + "id": "square_of_upward_ocean_mass_transport", "type": "standard_name", "name": "square_of_upward_ocean_mass_transport", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). Ocean transport means transport by all processes, both sea water and sea ice. \"square_of_X\" means X*X.", diff --git a/data_descriptors/standard_name/stagnation_temperature_in_air.json b/data_descriptors/standard_name/stagnation_temperature_in_air.json index 3f75cd7cb..7a1d95bf2 100644 --- a/data_descriptors/standard_name/stagnation_temperature_in_air.json +++ b/data_descriptors/standard_name/stagnation_temperature_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stagnation_temperature_in_air", + "id": "stagnation_temperature_in_air", "type": "standard_name", "name": "stagnation_temperature_in_air", "description": "In thermodynamics and fluid mechanics, stagnation temperature is the temperature at a stagnation point in a fluid flow. At a stagnation point the speed of the fluid is zero and all of the kinetic energy has been converted to internal energy and is added to the local static enthalpy. In both compressible and incompressible fluid flow, the stagnation temperature is equal to the total temperature at all points on the streamline leading to the stagnation point. In aviation, stagnation temperature is known as total air temperature and is measured by a temperature probe mounted on the surface of the aircraft. The probe is designed to bring the air to rest relative to the aircraft. As the air is brought to rest, kinetic energy is converted to internal energy. The air is compressed and experiences an adiabatic increase in temperature. Therefore, total air temperature is higher than the static (or ambient) air temperature. Total air temperature is an essential input to an air data computer in order to enable computation of static air temperature and hence true airspeed. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/status_flag.json b/data_descriptors/standard_name/status_flag.json index c241b78e1..99bad5922 100644 --- a/data_descriptors/standard_name/status_flag.json +++ b/data_descriptors/standard_name/status_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/status_flag", + "id": "status_flag", "type": "standard_name", "name": "status_flag", "description": "A variable with the standard name of status_flag contains an indication of quality or other status of another data variable. This may include the status of the instrument producing the data as well as data quality information. The linkage between the data variable and the variable with the standard_name of status_flag is achieved using the ancillary_variables attribute. A variable which contains purely quality information may use the standard name of quality_flag to provide an assessed quality of the corresponding data.", diff --git a/data_descriptors/standard_name/stem_mass_content_of_carbon.json b/data_descriptors/standard_name/stem_mass_content_of_carbon.json index d3c8c58cd..6c2a9f417 100644 --- a/data_descriptors/standard_name/stem_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/stem_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stem_mass_content_of_carbon", + "id": "stem_mass_content_of_carbon", "type": "standard_name", "name": "stem_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. The stem of a plant is the axis that bears buds and shoots with leaves and, at its basal end, roots. Its function is to carry water and nutrients. Examples include the stalk of a plant or the main trunk of a tree.", diff --git a/data_descriptors/standard_name/stem_mass_content_of_nitrogen.json b/data_descriptors/standard_name/stem_mass_content_of_nitrogen.json index a112a6820..cb0c0e634 100644 --- a/data_descriptors/standard_name/stem_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/stem_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stem_mass_content_of_nitrogen", + "id": "stem_mass_content_of_nitrogen", "type": "standard_name", "name": "stem_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. The stem of a plant is the axis that bears buds and shoots with leaves and, at its basal end, roots. Its function is to carry water and nutrients. Examples include the stalk of a plant or the main trunk of a tree.", diff --git a/data_descriptors/standard_name/steric_change_in_mean_sea_level.json b/data_descriptors/standard_name/steric_change_in_mean_sea_level.json index 25b7ab9d0..05b8eeb3a 100644 --- a/data_descriptors/standard_name/steric_change_in_mean_sea_level.json +++ b/data_descriptors/standard_name/steric_change_in_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/steric_change_in_mean_sea_level", + "id": "steric_change_in_mean_sea_level", "type": "standard_name", "name": "steric_change_in_mean_sea_level", "description": "Steric sea level change is caused by changes in sea water density due to changes in temperature (thermosteric) and salinity (halosteric). \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. Zero mean sea level change is an arbitrary level. The sum of the quantities with standard names thermosteric_change_in_mean_sea_level and halosteric_change_in_mean_sea_level has the standard name steric_change_in_mean_sea_level.", diff --git a/data_descriptors/standard_name/steric_change_in_sea_surface_height.json b/data_descriptors/standard_name/steric_change_in_sea_surface_height.json index 968214d40..560768f56 100644 --- a/data_descriptors/standard_name/steric_change_in_sea_surface_height.json +++ b/data_descriptors/standard_name/steric_change_in_sea_surface_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/steric_change_in_sea_surface_height", + "id": "steric_change_in_sea_surface_height", "type": "standard_name", "name": "steric_change_in_sea_surface_height", "description": "\"Sea surface height\" is a time-varying quantity. The steric change in sea surface height is the change in height that a water column of standard temperature zero degrees Celsius and practical salinity S=35.0 would undergo when its temperature and salinity are changed to the observed values. The sum of the quantities with standard names thermosteric_change_in_sea_surface_height and halosteric_change_in_sea_surface_height is the total steric change in the water column height, which has the standard name of steric_change_in_sea_surface_height. The sum of the quantities with standard names sea_water_mass_per_unit_area_expressed_as_thickness and steric_change_in_sea_surface_height is the total thickness of the sea water column.", diff --git a/data_descriptors/standard_name/storm_motion_speed.json b/data_descriptors/standard_name/storm_motion_speed.json index 1dc9ad3e9..9daadd7ea 100644 --- a/data_descriptors/standard_name/storm_motion_speed.json +++ b/data_descriptors/standard_name/storm_motion_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/storm_motion_speed", + "id": "storm_motion_speed", "type": "standard_name", "name": "storm_motion_speed", "description": "Storm motion speed is defined as a two dimensional velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) It is defined as the average speed of a supercell, and the direction the storm will move from. It is not dependent on the orientation of the ground-relative winds. Storm motion speed generally follows the methodology outlined in Bunkers et al. (2000).", diff --git a/data_descriptors/standard_name/stratiform_cloud_area_fraction.json b/data_descriptors/standard_name/stratiform_cloud_area_fraction.json index ba4db6147..fc92d6e36 100644 --- a/data_descriptors/standard_name/stratiform_cloud_area_fraction.json +++ b/data_descriptors/standard_name/stratiform_cloud_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_cloud_area_fraction", + "id": "stratiform_cloud_area_fraction", "type": "standard_name", "name": "stratiform_cloud_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. To specify which area is quantified by a variable with standard name area_fraction, provide a coordinate variable or scalar coordinate variable with standard name area_type. Alternatively, if one is defined, use a more specific standard name of X_area_fraction for the fraction of horizontal area occupied by X. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/stratiform_cloud_area_fraction_in_atmosphere_layer.json b/data_descriptors/standard_name/stratiform_cloud_area_fraction_in_atmosphere_layer.json index 4a4fc7f86..c356e5c3a 100644 --- a/data_descriptors/standard_name/stratiform_cloud_area_fraction_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/stratiform_cloud_area_fraction_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_cloud_area_fraction_in_atmosphere_layer", + "id": "stratiform_cloud_area_fraction_in_atmosphere_layer", "type": "standard_name", "name": "stratiform_cloud_area_fraction_in_atmosphere_layer", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Standard names also exist for high, medium and low cloud types. Standard names referring only to \"cloud_area_fraction\" should be used for quantities for the whole atmosphere column. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). Cloud area fraction is also called \"cloud amount\" and \"cloud cover\".", diff --git a/data_descriptors/standard_name/stratiform_cloud_longwave_emissivity.json b/data_descriptors/standard_name/stratiform_cloud_longwave_emissivity.json index b96d656b7..c22b64e60 100644 --- a/data_descriptors/standard_name/stratiform_cloud_longwave_emissivity.json +++ b/data_descriptors/standard_name/stratiform_cloud_longwave_emissivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_cloud_longwave_emissivity", + "id": "stratiform_cloud_longwave_emissivity", "type": "standard_name", "name": "stratiform_cloud_longwave_emissivity", "description": "Emissivity is the ratio of the power emitted by an object to the power that would be emitted by a perfect black body having the same temperature as the object. The emissivity is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength or radiation_frequency is included to specify either the wavelength or frequency. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"longwave\" means longwave radiation.", diff --git a/data_descriptors/standard_name/stratiform_graupel_fall_amount.json b/data_descriptors/standard_name/stratiform_graupel_fall_amount.json index 16f368ed2..51550c8de 100644 --- a/data_descriptors/standard_name/stratiform_graupel_fall_amount.json +++ b/data_descriptors/standard_name/stratiform_graupel_fall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_graupel_fall_amount", + "id": "stratiform_graupel_fall_amount", "type": "standard_name", "name": "stratiform_graupel_fall_amount", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. There are also separate standard names for hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/stratiform_graupel_flux.json b/data_descriptors/standard_name/stratiform_graupel_flux.json index 2c97b9890..d89ab49bc 100644 --- a/data_descriptors/standard_name/stratiform_graupel_flux.json +++ b/data_descriptors/standard_name/stratiform_graupel_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_graupel_flux", + "id": "stratiform_graupel_flux", "type": "standard_name", "name": "stratiform_graupel_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. There are also separate standard names for hail. Standard names for \"graupel_and_hail\" should be used to describe data produced by models that do not distinguish between hail and graupel.", diff --git a/data_descriptors/standard_name/stratiform_precipitation_amount.json b/data_descriptors/standard_name/stratiform_precipitation_amount.json index 1086d895a..4070e710f 100644 --- a/data_descriptors/standard_name/stratiform_precipitation_amount.json +++ b/data_descriptors/standard_name/stratiform_precipitation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_precipitation_amount", + "id": "stratiform_precipitation_amount", "type": "standard_name", "name": "stratiform_precipitation_amount", "description": "\"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/stratiform_precipitation_flux.json b/data_descriptors/standard_name/stratiform_precipitation_flux.json index c170bc48b..51e8da59f 100644 --- a/data_descriptors/standard_name/stratiform_precipitation_flux.json +++ b/data_descriptors/standard_name/stratiform_precipitation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_precipitation_flux", + "id": "stratiform_precipitation_flux", "type": "standard_name", "name": "stratiform_precipitation_flux", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/stratiform_rainfall_amount.json b/data_descriptors/standard_name/stratiform_rainfall_amount.json index fb85886ff..13d3eca4b 100644 --- a/data_descriptors/standard_name/stratiform_rainfall_amount.json +++ b/data_descriptors/standard_name/stratiform_rainfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_rainfall_amount", + "id": "stratiform_rainfall_amount", "type": "standard_name", "name": "stratiform_rainfall_amount", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/stratiform_rainfall_flux.json b/data_descriptors/standard_name/stratiform_rainfall_flux.json index 3e20276f8..5a2c3209a 100644 --- a/data_descriptors/standard_name/stratiform_rainfall_flux.json +++ b/data_descriptors/standard_name/stratiform_rainfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_rainfall_flux", + "id": "stratiform_rainfall_flux", "type": "standard_name", "name": "stratiform_rainfall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", diff --git a/data_descriptors/standard_name/stratiform_rainfall_rate.json b/data_descriptors/standard_name/stratiform_rainfall_rate.json index e2390c87f..28abe2455 100644 --- a/data_descriptors/standard_name/stratiform_rainfall_rate.json +++ b/data_descriptors/standard_name/stratiform_rainfall_rate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_rainfall_rate", + "id": "stratiform_rainfall_rate", "type": "standard_name", "name": "stratiform_rainfall_rate", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", diff --git a/data_descriptors/standard_name/stratiform_snowfall_amount.json b/data_descriptors/standard_name/stratiform_snowfall_amount.json index 2f0909daf..8c194b0d0 100644 --- a/data_descriptors/standard_name/stratiform_snowfall_amount.json +++ b/data_descriptors/standard_name/stratiform_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_snowfall_amount", + "id": "stratiform_snowfall_amount", "type": "standard_name", "name": "stratiform_snowfall_amount", "description": "Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/stratiform_snowfall_flux.json b/data_descriptors/standard_name/stratiform_snowfall_flux.json index 86e7f9209..72b7acd32 100644 --- a/data_descriptors/standard_name/stratiform_snowfall_flux.json +++ b/data_descriptors/standard_name/stratiform_snowfall_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratiform_snowfall_flux", + "id": "stratiform_snowfall_flux", "type": "standard_name", "name": "stratiform_snowfall_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", diff --git a/data_descriptors/standard_name/stratosphere_mole_content_of_nitrogen_dioxide.json b/data_descriptors/standard_name/stratosphere_mole_content_of_nitrogen_dioxide.json index 67811f40a..9b0043e8e 100644 --- a/data_descriptors/standard_name/stratosphere_mole_content_of_nitrogen_dioxide.json +++ b/data_descriptors/standard_name/stratosphere_mole_content_of_nitrogen_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratosphere_mole_content_of_nitrogen_dioxide", + "id": "stratosphere_mole_content_of_nitrogen_dioxide", "type": "standard_name", "name": "stratosphere_mole_content_of_nitrogen_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"stratosphere content\" of a quantity refers to the vertical integral from the tropopause to the stratopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for nitrogen_dioxide is NO2.", diff --git a/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_ambient_aerosol_particles.json index e49f6f766..6aa97ba59 100644 --- a/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratosphere_optical_thickness_due_to_ambient_aerosol_particles", + "id": "stratosphere_optical_thickness_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "stratosphere_optical_thickness_due_to_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The stratosphere optical thickness applies to radiation passing through the atmosphere layer between the tropopause and stratopause. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json b/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json index 195e0ec4d..bd0e3e578 100644 --- a/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", + "id": "stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", "type": "standard_name", "name": "stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The stratosphere optical thickness applies to radiation passing through the atmosphere layer between the tropopause and stratopause. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles.json b/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles.json index 4d0cc988b..bbf8c867e 100644 --- a/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles", + "id": "stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles", "type": "standard_name", "name": "stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles", "description": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-\"optical_thickness\") on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The stratosphere optical thickness applies to radiation passing through the atmosphere layer between the tropopause and stratopause. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions.", diff --git a/data_descriptors/standard_name/subsurface_litter_mass_content_of_carbon.json b/data_descriptors/standard_name/subsurface_litter_mass_content_of_carbon.json index 40dcdfa2e..8068e176b 100644 --- a/data_descriptors/standard_name/subsurface_litter_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/subsurface_litter_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/subsurface_litter_mass_content_of_carbon", + "id": "subsurface_litter_mass_content_of_carbon", "type": "standard_name", "name": "subsurface_litter_mass_content_of_carbon", "description": "\"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. \"Subsurface litter\" means the part of the litter mixed within the soil below the surface. \"Content\" indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", diff --git a/data_descriptors/standard_name/subsurface_litter_mass_content_of_nitrogen.json b/data_descriptors/standard_name/subsurface_litter_mass_content_of_nitrogen.json index af18e8142..2e0475a8b 100644 --- a/data_descriptors/standard_name/subsurface_litter_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/subsurface_litter_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/subsurface_litter_mass_content_of_nitrogen", + "id": "subsurface_litter_mass_content_of_nitrogen", "type": "standard_name", "name": "subsurface_litter_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. \"Subsurface litter\" means the part of the litter mixed within the soil below the surface. The sum of the quantities with standard names wood_debris_mass_content_of_nitrogen, surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen is the total nitrogen mass content of dead plant material.", diff --git a/data_descriptors/standard_name/subsurface_runoff_amount.json b/data_descriptors/standard_name/subsurface_runoff_amount.json index f8a7fcca4..4f96d5b64 100644 --- a/data_descriptors/standard_name/subsurface_runoff_amount.json +++ b/data_descriptors/standard_name/subsurface_runoff_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/subsurface_runoff_amount", + "id": "subsurface_runoff_amount", "type": "standard_name", "name": "subsurface_runoff_amount", "description": "\"Amount\" means mass per unit area. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/subsurface_runoff_flux.json b/data_descriptors/standard_name/subsurface_runoff_flux.json index bfc0adf1d..555b3a916 100644 --- a/data_descriptors/standard_name/subsurface_runoff_flux.json +++ b/data_descriptors/standard_name/subsurface_runoff_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/subsurface_runoff_flux", + "id": "subsurface_runoff_flux", "type": "standard_name", "name": "subsurface_runoff_flux", "description": "Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/sunglint_angle.json b/data_descriptors/standard_name/sunglint_angle.json index e247e7192..b65bbc113 100644 --- a/data_descriptors/standard_name/sunglint_angle.json +++ b/data_descriptors/standard_name/sunglint_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sunglint_angle", + "id": "sunglint_angle", "type": "standard_name", "name": "sunglint_angle", "description": "The angle between an incident beam of solar radiation and the outgoing beam specularly reflected at a sea surface.", diff --git a/data_descriptors/standard_name/sunlit_binary_mask.json b/data_descriptors/standard_name/sunlit_binary_mask.json index 6a76a2f2d..8d3c9fa58 100644 --- a/data_descriptors/standard_name/sunlit_binary_mask.json +++ b/data_descriptors/standard_name/sunlit_binary_mask.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/sunlit_binary_mask", + "id": "sunlit_binary_mask", "type": "standard_name", "name": "sunlit_binary_mask", "description": "X_binary_mask has 1 where condition X is met, 0 elsewhere.", diff --git a/data_descriptors/standard_name/surface_air_pressure.json b/data_descriptors/standard_name/surface_air_pressure.json index 1ceafe85e..486a997e1 100644 --- a/data_descriptors/standard_name/surface_air_pressure.json +++ b/data_descriptors/standard_name/surface_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_air_pressure", + "id": "surface_air_pressure", "type": "standard_name", "name": "surface_air_pressure", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/surface_albedo.json b/data_descriptors/standard_name/surface_albedo.json index 71a814b0c..f81d67fe5 100644 --- a/data_descriptors/standard_name/surface_albedo.json +++ b/data_descriptors/standard_name/surface_albedo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_albedo", + "id": "surface_albedo", "type": "standard_name", "name": "surface_albedo", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum. To specify the nature of the surface a cell_methods attribute should be supplied as described in Chapter 7.3.3 of the CF Conventions.", diff --git a/data_descriptors/standard_name/surface_albedo_assuming_deep_snow.json b/data_descriptors/standard_name/surface_albedo_assuming_deep_snow.json index a654da75e..3db3a79a2 100644 --- a/data_descriptors/standard_name/surface_albedo_assuming_deep_snow.json +++ b/data_descriptors/standard_name/surface_albedo_assuming_deep_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_albedo_assuming_deep_snow", + "id": "surface_albedo_assuming_deep_snow", "type": "standard_name", "name": "surface_albedo_assuming_deep_snow", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/surface_albedo_assuming_no_snow.json b/data_descriptors/standard_name/surface_albedo_assuming_no_snow.json index b408f891e..eceef5eaf 100644 --- a/data_descriptors/standard_name/surface_albedo_assuming_no_snow.json +++ b/data_descriptors/standard_name/surface_albedo_assuming_no_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_albedo_assuming_no_snow", + "id": "surface_albedo_assuming_no_snow", "type": "standard_name", "name": "surface_albedo_assuming_no_snow", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Albedo is the ratio of outgoing to incoming shortwave irradiance, where 'shortwave irradiance' means that both the incoming and outgoing radiation are integrated across the solar spectrum. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/surface_altitude.json b/data_descriptors/standard_name/surface_altitude.json index 022947190..1ea6adf58 100644 --- a/data_descriptors/standard_name/surface_altitude.json +++ b/data_descriptors/standard_name/surface_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_altitude", + "id": "surface_altitude", "type": "standard_name", "name": "surface_altitude", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/surface_backwards_scattering_coefficient_of_radar_wave.json b/data_descriptors/standard_name/surface_backwards_scattering_coefficient_of_radar_wave.json index 9eeaa01b2..74f32616a 100644 --- a/data_descriptors/standard_name/surface_backwards_scattering_coefficient_of_radar_wave.json +++ b/data_descriptors/standard_name/surface_backwards_scattering_coefficient_of_radar_wave.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_backwards_scattering_coefficient_of_radar_wave", + "id": "surface_backwards_scattering_coefficient_of_radar_wave", "type": "standard_name", "name": "surface_backwards_scattering_coefficient_of_radar_wave", "description": "The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Scattering of radiation is its deflection from its incident path without loss of energy. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity.", diff --git a/data_descriptors/standard_name/surface_bidirectional_reflectance.json b/data_descriptors/standard_name/surface_bidirectional_reflectance.json index 8cdba6414..ff473c81d 100644 --- a/data_descriptors/standard_name/surface_bidirectional_reflectance.json +++ b/data_descriptors/standard_name/surface_bidirectional_reflectance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_bidirectional_reflectance", + "id": "surface_bidirectional_reflectance", "type": "standard_name", "name": "surface_bidirectional_reflectance", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Bidirectional_reflectance\" depends on the angles of incident and measured radiation. Reflectance is the ratio of the energy of the reflected to the incident radiation. A coordinate variable of radiation_wavelength or radiation_frequency can be used to specify the wavelength or frequency, respectively, of the radiation.", diff --git a/data_descriptors/standard_name/surface_brightness_temperature.json b/data_descriptors/standard_name/surface_brightness_temperature.json index 506fbc563..104da205b 100644 --- a/data_descriptors/standard_name/surface_brightness_temperature.json +++ b/data_descriptors/standard_name/surface_brightness_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_brightness_temperature", + "id": "surface_brightness_temperature", "type": "standard_name", "name": "surface_brightness_temperature", "description": "The surface called \"surface\" means the lower boundary of the atmosphere.The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/surface_buoyancy_flux_into_air.json b/data_descriptors/standard_name/surface_buoyancy_flux_into_air.json index c33ae632b..1b232fe91 100644 --- a/data_descriptors/standard_name/surface_buoyancy_flux_into_air.json +++ b/data_descriptors/standard_name/surface_buoyancy_flux_into_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_buoyancy_flux_into_air", + "id": "surface_buoyancy_flux_into_air", "type": "standard_name", "name": "surface_buoyancy_flux_into_air", "description": "A variable quantifying net density gains or losses in air parcel buoyancy based on turbulent heat and moisture fluxes, represented by virtual temperature flux, at the air-sea interface. Positive values indicate a buoyancy flux out of the ocean (into the air) that will destabilize the atmosphere.", diff --git a/data_descriptors/standard_name/surface_buoyancy_flux_into_sea_water.json b/data_descriptors/standard_name/surface_buoyancy_flux_into_sea_water.json index 77cbe35cb..87d535c55 100644 --- a/data_descriptors/standard_name/surface_buoyancy_flux_into_sea_water.json +++ b/data_descriptors/standard_name/surface_buoyancy_flux_into_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_buoyancy_flux_into_sea_water", + "id": "surface_buoyancy_flux_into_sea_water", "type": "standard_name", "name": "surface_buoyancy_flux_into_sea_water", "description": "A variable quantifying net density gains or losses in water parcel buoyancy based on thermal (net surface heat flux) and haline (precipitation minus evaporation) forcings at the air-sea interface. A positive value indicates a buoyancy flux into the ocean that will stabilize (i.e., stratify) the surface ocean layer.", diff --git a/data_descriptors/standard_name/surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air.json b/data_descriptors/standard_name/surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air.json index 242d56b0c..2e92e1ad2 100644 --- a/data_descriptors/standard_name/surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air.json +++ b/data_descriptors/standard_name/surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air", + "id": "surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air", "type": "standard_name", "name": "surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", diff --git a/data_descriptors/standard_name/surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air.json b/data_descriptors/standard_name/surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air.json index 4d25caf06..c22cbee3b 100644 --- a/data_descriptors/standard_name/surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air.json +++ b/data_descriptors/standard_name/surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air", + "id": "surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air", "type": "standard_name", "name": "surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", diff --git a/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water.json b/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water.json index 8e3170008..35baf7aa9 100644 --- a/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water.json +++ b/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water", + "id": "surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water", "type": "standard_name", "name": "surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The partial pressure difference between air and sea water is positive when the partial pressure in air is greater than the partial pressure of the dissolved gas in sea water.", diff --git a/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air.json b/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air.json index bc805b3c5..e8a7ac7a5 100644 --- a/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air.json +++ b/data_descriptors/standard_name/surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air", + "id": "surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air", "type": "standard_name", "name": "surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", diff --git a/data_descriptors/standard_name/surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air.json b/data_descriptors/standard_name/surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air.json index 33167dbed..fc1832af4 100644 --- a/data_descriptors/standard_name/surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air.json +++ b/data_descriptors/standard_name/surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air", + "id": "surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air", "type": "standard_name", "name": "surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. \"Diffuse\" radiation is radiation that has been scattered by gas molecules in the atmosphere and by particles such as cloud droplets and aerosols. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air.json index 28ed90ad4..29cc5d3be 100644 --- a/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_diffuse_downwelling_shortwave_flux_in_air", + "id": "surface_diffuse_downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "surface_diffuse_downwelling_shortwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The term \"shortwave\" means shortwave radiation. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Diffuse\" radiation is radiation that has been scattered by gas molecules in the atmosphere and by particles such as cloud droplets and aerosols. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json index 3c0a450b5..389d5fc7e 100644 --- a/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", + "id": "surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Diffuse\" radiation is radiation that has been scattered by gas molecules in the atmosphere and by particles such as cloud droplets and aerosols. The term \"shortwave\" means shortwave radiation. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_diffuse_shortwave_hemispherical_reflectance.json b/data_descriptors/standard_name/surface_diffuse_shortwave_hemispherical_reflectance.json index 9a1ac7403..265409cd9 100644 --- a/data_descriptors/standard_name/surface_diffuse_shortwave_hemispherical_reflectance.json +++ b/data_descriptors/standard_name/surface_diffuse_shortwave_hemispherical_reflectance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_diffuse_shortwave_hemispherical_reflectance", + "id": "surface_diffuse_shortwave_hemispherical_reflectance", "type": "standard_name", "name": "surface_diffuse_shortwave_hemispherical_reflectance", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Diffuse\" radiation is radiation that has been scattered by gas molecules in the atmosphere and by particles such as cloud droplets and aerosols. The term \"shortwave\" means shortwave radiation. Hemispherical reflectance is the ratio of the energy of the reflected to the incident radiation. This term gives the fraction of the surface_diffuse_downwelling_shortwave_flux_in_air which is reflected. If the diffuse radiation is isotropic, this term is equivalent to the integral of surface_bidirectional_reflectance over all incident angles and over all outgoing angles in the hemisphere above the surface. A coordinate variable of radiation_wavelength or radiation_frequency can be used to specify the wavelength or frequency, respectively, of the radiation. Shortwave hemispherical reflectance is related to albedo, but albedo is defined in terms of the fraction of the full spectrum of incident solar radiation which is reflected. It is related to the hemispherical reflectance averaged over all wavelengths using a weighting proportional to the incident radiative flux.", diff --git a/data_descriptors/standard_name/surface_direct_along_beam_shortwave_flux_in_air.json b/data_descriptors/standard_name/surface_direct_along_beam_shortwave_flux_in_air.json index a6eebab82..51382c9a5 100644 --- a/data_descriptors/standard_name/surface_direct_along_beam_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_direct_along_beam_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_direct_along_beam_shortwave_flux_in_air", + "id": "surface_direct_along_beam_shortwave_flux_in_air", "type": "standard_name", "name": "surface_direct_along_beam_shortwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Direct\" (also known as \"beam\") radiation is radiation that has followed a direct path from the sun and is alternatively known as \"direct insolation\". The phrase \"along_beam\" refers to direct radiation on a plane perpendicular to the direction of the sun. This is in contrast to standard names such as direct_downwelling_shortwave_flux_in_air, where the radiation falls on a horizontal plane at the earth surface. The term \"shortwave\" means shortwave radiation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The quantity with standard name surface_direct_along_beam_shortwave_flux_in_air is also called Direct Normal Irradiance (DNI) in the solar energy industry.", diff --git a/data_descriptors/standard_name/surface_direct_downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/surface_direct_downwelling_shortwave_flux_in_air.json index cb771fe5d..522920419 100644 --- a/data_descriptors/standard_name/surface_direct_downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_direct_downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_direct_downwelling_shortwave_flux_in_air", + "id": "surface_direct_downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "surface_direct_downwelling_shortwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Direct\" (also known as \"beam\") radiation is radiation that has followed a direct path from the sun and is alternatively known as \"direct insolation\". Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_direct_shortwave_hemispherical_reflectance.json b/data_descriptors/standard_name/surface_direct_shortwave_hemispherical_reflectance.json index c5b98de81..ebfa60133 100644 --- a/data_descriptors/standard_name/surface_direct_shortwave_hemispherical_reflectance.json +++ b/data_descriptors/standard_name/surface_direct_shortwave_hemispherical_reflectance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_direct_shortwave_hemispherical_reflectance", + "id": "surface_direct_shortwave_hemispherical_reflectance", "type": "standard_name", "name": "surface_direct_shortwave_hemispherical_reflectance", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Direct\" (also known as \"beam\") radiation is radiation that has followed a direct path from the sun and is alternatively known as \"direct insolation\". The term \"shortwave\" means shortwave radiation. Hemispherical reflectance is the ratio of the energy of the reflected to the incident radiation. This term gives the fraction of the surface_direct_downwelling_shortwave_flux_in_air which is reflected. It is equivalent to the surface_bidirectional_reflectance at the incident angle of the incoming solar radiation and integrated over all outgoing angles in the hemisphere above the surface. A coordinate variable of radiation_wavelength or radiation_frequency can be used to specify the wavelength or frequency, respectively, of the radiation. Shortwave hemispherical reflectance is related to albedo, but albedo is defined in terms of the fraction of the full spectrum of incident solar radiation which is reflected. It is related to the hemispherical reflectance averaged over all wavelengths using a weighting proportional to the incident radiation flux.", diff --git a/data_descriptors/standard_name/surface_downward_eastward_stress.json b/data_descriptors/standard_name/surface_downward_eastward_stress.json index bdfe6af0e..c647da454 100644 --- a/data_descriptors/standard_name/surface_downward_eastward_stress.json +++ b/data_descriptors/standard_name/surface_downward_eastward_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_eastward_stress", + "id": "surface_downward_eastward_stress", "type": "standard_name", "name": "surface_downward_eastward_stress", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward.", diff --git a/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_boundary_layer_mixing.json index dad567dd1..ce42e3308 100644 --- a/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_eastward_stress_due_to_boundary_layer_mixing", + "id": "surface_downward_eastward_stress_due_to_boundary_layer_mixing", "type": "standard_name", "name": "surface_downward_eastward_stress_due_to_boundary_layer_mixing", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_ocean_viscous_dissipation.json b/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_ocean_viscous_dissipation.json index 2ec70acf4..dd931c21d 100644 --- a/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_ocean_viscous_dissipation.json +++ b/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_ocean_viscous_dissipation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_eastward_stress_due_to_ocean_viscous_dissipation", + "id": "surface_downward_eastward_stress_due_to_ocean_viscous_dissipation", "type": "standard_name", "name": "surface_downward_eastward_stress_due_to_ocean_viscous_dissipation", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Eastward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Viscosity\" means the stress associated with viscous effects at the sea surface and is equivalent to the turbulent stress just outside the viscous sublayer.", diff --git a/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_sea_surface_waves.json b/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_sea_surface_waves.json index 49a6c2008..7e7751b38 100644 --- a/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_sea_surface_waves.json +++ b/data_descriptors/standard_name/surface_downward_eastward_stress_due_to_sea_surface_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_eastward_stress_due_to_sea_surface_waves", + "id": "surface_downward_eastward_stress_due_to_sea_surface_waves", "type": "standard_name", "name": "surface_downward_eastward_stress_due_to_sea_surface_waves", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Eastward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward eastward\" indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea surface waves\" means the stress associated with form drag over sea surface waves.", diff --git a/data_descriptors/standard_name/surface_downward_heat_flux_in_air.json b/data_descriptors/standard_name/surface_downward_heat_flux_in_air.json index 4754f18f3..aca2f2e1b 100644 --- a/data_descriptors/standard_name/surface_downward_heat_flux_in_air.json +++ b/data_descriptors/standard_name/surface_downward_heat_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_heat_flux_in_air", + "id": "surface_downward_heat_flux_in_air", "type": "standard_name", "name": "surface_downward_heat_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The vertical heat flux in air is the sum of all heat fluxes i.e. radiative, latent and sensible. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_ice.json b/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_ice.json index 2d490ad79..759ae58ea 100644 --- a/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_ice.json +++ b/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_heat_flux_in_sea_ice", + "id": "surface_downward_heat_flux_in_sea_ice", "type": "standard_name", "name": "surface_downward_heat_flux_in_sea_ice", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_water.json b/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_water.json index a68416c0c..6fddbf46f 100644 --- a/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downward_heat_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_heat_flux_in_sea_water", + "id": "surface_downward_heat_flux_in_sea_water", "type": "standard_name", "name": "surface_downward_heat_flux_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Water\" means water in all phases, including frozen i.e. ice and snow. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downward_heat_flux_in_snow.json b/data_descriptors/standard_name/surface_downward_heat_flux_in_snow.json index c80b84eaa..67ff8654a 100644 --- a/data_descriptors/standard_name/surface_downward_heat_flux_in_snow.json +++ b/data_descriptors/standard_name/surface_downward_heat_flux_in_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_heat_flux_in_snow", + "id": "surface_downward_heat_flux_in_snow", "type": "standard_name", "name": "surface_downward_heat_flux_in_snow", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_downward_latent_heat_flux.json b/data_descriptors/standard_name/surface_downward_latent_heat_flux.json index 5b6b11aca..78b967754 100644 --- a/data_descriptors/standard_name/surface_downward_latent_heat_flux.json +++ b/data_descriptors/standard_name/surface_downward_latent_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_latent_heat_flux", + "id": "surface_downward_latent_heat_flux", "type": "standard_name", "name": "surface_downward_latent_heat_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C.json index 4e96eef8f..ddc717283 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C", + "id": "surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C", "type": "standard_name", "name": "surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon.json index cf7a920e0..a2710d839 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", + "id": "surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", "type": "standard_name", "name": "surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_ammonia.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_ammonia.json index 08d7ca05f..5593ea6c0 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_ammonia.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_ammonia.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_ammonia", + "id": "surface_downward_mass_flux_of_ammonia", "type": "standard_name", "name": "surface_downward_mass_flux_of_ammonia", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon.json index b552b1b7d..5089e4737 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon", + "id": "surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon", "type": "standard_name", "name": "surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon.json index 9c2acaa4b..145fa82c6 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon", + "id": "surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon", "type": "standard_name", "name": "surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon.json index 37cc05f0f..dc0447748 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon", + "id": "surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon", "type": "standard_name", "name": "surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption.json index 5c5ac542a..afc347396 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption", + "id": "surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption", "type": "standard_name", "name": "surface_downward_mass_flux_of_methane_due_to_non_wetland_soil_biological_consumption", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Non-wetland soils are all soils except for wetlands. Wetlands are areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season. The precise conditions under which non-wetland soils produce and consume methane can vary between models.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption.json index c2bcfada2..3b832d370 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption", + "id": "surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption", "type": "standard_name", "name": "surface_downward_mass_flux_of_methane_due_to_soil_biological_consumption", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption.json index 2a412b077..770fd1c23 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption", + "id": "surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption", "type": "standard_name", "name": "surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Wetlands are areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season. The precise conditions under which wetlands produce and consume methane can vary between models.", diff --git a/data_descriptors/standard_name/surface_downward_mass_flux_of_water_due_to_irrigation.json b/data_descriptors/standard_name/surface_downward_mass_flux_of_water_due_to_irrigation.json index 9f872d71c..dca97d6da 100644 --- a/data_descriptors/standard_name/surface_downward_mass_flux_of_water_due_to_irrigation.json +++ b/data_descriptors/standard_name/surface_downward_mass_flux_of_water_due_to_irrigation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mass_flux_of_water_due_to_irrigation", + "id": "surface_downward_mass_flux_of_water_due_to_irrigation", "type": "standard_name", "name": "surface_downward_mass_flux_of_water_due_to_irrigation", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface called \"surface\" means the lower boundary of the atmosphere. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Irrigation\" includes water used to sustain crops, trees, pastures and urban lawns.", diff --git a/data_descriptors/standard_name/surface_downward_mole_flux_of_carbon_dioxide.json b/data_descriptors/standard_name/surface_downward_mole_flux_of_carbon_dioxide.json index 2f8a970c7..21781573d 100644 --- a/data_descriptors/standard_name/surface_downward_mole_flux_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/surface_downward_mole_flux_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mole_flux_of_carbon_dioxide", + "id": "surface_downward_mole_flux_of_carbon_dioxide", "type": "standard_name", "name": "surface_downward_mole_flux_of_carbon_dioxide", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. The standard name surface_upward_mole_flux_of_carbon_dioxide should be used to label data in which the flux is positive when directed upward. The standard name \"surface_carbon_dioxide_mole_flux\" is deprecated because it does not specify in which direction the flux is positive. Any data having the standard name \"surface_carbon_dioxide_mole_flux\" should be examined carefully to determine which sign convention was used.", diff --git a/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc11.json b/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc11.json index 955265f7a..2d12d3ea0 100644 --- a/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc11.json +++ b/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc11.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mole_flux_of_cfc11", + "id": "surface_downward_mole_flux_of_cfc11", "type": "standard_name", "name": "surface_downward_mole_flux_of_cfc11", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc12.json b/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc12.json index ecfc69f7a..a7a33995d 100644 --- a/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc12.json +++ b/data_descriptors/standard_name/surface_downward_mole_flux_of_cfc12.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mole_flux_of_cfc12", + "id": "surface_downward_mole_flux_of_cfc12", "type": "standard_name", "name": "surface_downward_mole_flux_of_cfc12", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/surface_downward_mole_flux_of_molecular_oxygen.json b/data_descriptors/standard_name/surface_downward_mole_flux_of_molecular_oxygen.json index ac7dd42ea..808a1f66e 100644 --- a/data_descriptors/standard_name/surface_downward_mole_flux_of_molecular_oxygen.json +++ b/data_descriptors/standard_name/surface_downward_mole_flux_of_molecular_oxygen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mole_flux_of_molecular_oxygen", + "id": "surface_downward_mole_flux_of_molecular_oxygen", "type": "standard_name", "name": "surface_downward_mole_flux_of_molecular_oxygen", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_downward_mole_flux_of_sulfur_hexafluoride.json b/data_descriptors/standard_name/surface_downward_mole_flux_of_sulfur_hexafluoride.json index e73aadb29..827cbc824 100644 --- a/data_descriptors/standard_name/surface_downward_mole_flux_of_sulfur_hexafluoride.json +++ b/data_descriptors/standard_name/surface_downward_mole_flux_of_sulfur_hexafluoride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_mole_flux_of_sulfur_hexafluoride", + "id": "surface_downward_mole_flux_of_sulfur_hexafluoride", "type": "standard_name", "name": "surface_downward_mole_flux_of_sulfur_hexafluoride", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula of sulfur hexafluoride is SF6.", diff --git a/data_descriptors/standard_name/surface_downward_northward_stress.json b/data_descriptors/standard_name/surface_downward_northward_stress.json index 1cb4f0fea..2dbff5a44 100644 --- a/data_descriptors/standard_name/surface_downward_northward_stress.json +++ b/data_descriptors/standard_name/surface_downward_northward_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_northward_stress", + "id": "surface_downward_northward_stress", "type": "standard_name", "name": "surface_downward_northward_stress", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward.", diff --git a/data_descriptors/standard_name/surface_downward_northward_stress_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/surface_downward_northward_stress_due_to_boundary_layer_mixing.json index 0c567fdb8..fcdc61598 100644 --- a/data_descriptors/standard_name/surface_downward_northward_stress_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/surface_downward_northward_stress_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_northward_stress_due_to_boundary_layer_mixing", + "id": "surface_downward_northward_stress_due_to_boundary_layer_mixing", "type": "standard_name", "name": "surface_downward_northward_stress_due_to_boundary_layer_mixing", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/surface_downward_northward_stress_due_to_ocean_viscous_dissipation.json b/data_descriptors/standard_name/surface_downward_northward_stress_due_to_ocean_viscous_dissipation.json index f79aa0f3a..c5b4f4be1 100644 --- a/data_descriptors/standard_name/surface_downward_northward_stress_due_to_ocean_viscous_dissipation.json +++ b/data_descriptors/standard_name/surface_downward_northward_stress_due_to_ocean_viscous_dissipation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_northward_stress_due_to_ocean_viscous_dissipation", + "id": "surface_downward_northward_stress_due_to_ocean_viscous_dissipation", "type": "standard_name", "name": "surface_downward_northward_stress_due_to_ocean_viscous_dissipation", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Viscosity\" means the stress associated with viscous effects at the sea surface and is equivalent to the turbulent stress just outside the viscous sublayer.", diff --git a/data_descriptors/standard_name/surface_downward_northward_stress_due_to_sea_surface_waves.json b/data_descriptors/standard_name/surface_downward_northward_stress_due_to_sea_surface_waves.json index c6123e5b7..045224f2b 100644 --- a/data_descriptors/standard_name/surface_downward_northward_stress_due_to_sea_surface_waves.json +++ b/data_descriptors/standard_name/surface_downward_northward_stress_due_to_sea_surface_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_northward_stress_due_to_sea_surface_waves", + "id": "surface_downward_northward_stress_due_to_sea_surface_waves", "type": "standard_name", "name": "surface_downward_northward_stress_due_to_sea_surface_waves", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Downward northward\" indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea surface waves\" means the stress associated with form drag over sea surface waves.", diff --git a/data_descriptors/standard_name/surface_downward_sensible_heat_flux.json b/data_descriptors/standard_name/surface_downward_sensible_heat_flux.json index 0e6c06c57..815f3c6f8 100644 --- a/data_descriptors/standard_name/surface_downward_sensible_heat_flux.json +++ b/data_descriptors/standard_name/surface_downward_sensible_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_sensible_heat_flux", + "id": "surface_downward_sensible_heat_flux", "type": "standard_name", "name": "surface_downward_sensible_heat_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface sensible heat flux, also called \"turbulent\" heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downward_water_flux.json b/data_descriptors/standard_name/surface_downward_water_flux.json index 00b398344..40d611873 100644 --- a/data_descriptors/standard_name/surface_downward_water_flux.json +++ b/data_descriptors/standard_name/surface_downward_water_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_water_flux", + "id": "surface_downward_water_flux", "type": "standard_name", "name": "surface_downward_water_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Water\" means water in all phases, including frozen i.e. ice and snow. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface water flux is the result of precipitation and evaporation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downward_x_stress.json b/data_descriptors/standard_name/surface_downward_x_stress.json index 12d5e8e69..4bfac393e 100644 --- a/data_descriptors/standard_name/surface_downward_x_stress.json +++ b/data_descriptors/standard_name/surface_downward_x_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_x_stress", + "id": "surface_downward_x_stress", "type": "standard_name", "name": "surface_downward_x_stress", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Downward x\" indicates the ZX component of a tensor. A downward x stress is a downward flux of momentum, which accelerates the lower medium in the direction of increasing x and and the upper medium in the direction of decreasing x.", diff --git a/data_descriptors/standard_name/surface_downward_x_stress_correction.json b/data_descriptors/standard_name/surface_downward_x_stress_correction.json index 4817027fc..a0be42484 100644 --- a/data_descriptors/standard_name/surface_downward_x_stress_correction.json +++ b/data_descriptors/standard_name/surface_downward_x_stress_correction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_x_stress_correction", + "id": "surface_downward_x_stress_correction", "type": "standard_name", "name": "surface_downward_x_stress_correction", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Downward x\" indicates the ZX component of a tensor. A downward x stress is a downward flux of momentum, which accelerates the lower medium in the direction of increasing x and and the upper medium in the direction of decreasing x. A positive correction is downward i.e. added to the ocean.", diff --git a/data_descriptors/standard_name/surface_downward_y_stress.json b/data_descriptors/standard_name/surface_downward_y_stress.json index 37ade57fa..4f0f6b94b 100644 --- a/data_descriptors/standard_name/surface_downward_y_stress.json +++ b/data_descriptors/standard_name/surface_downward_y_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_y_stress", + "id": "surface_downward_y_stress", "type": "standard_name", "name": "surface_downward_y_stress", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Downward y\" indicates the ZY component of a tensor. A downward y stress is a downward flux of momentum, which accelerates the lower medium in the direction of increasing y and and the upper medium in the direction of decreasing y.", diff --git a/data_descriptors/standard_name/surface_downward_y_stress_correction.json b/data_descriptors/standard_name/surface_downward_y_stress_correction.json index 2534f3945..db4df760a 100644 --- a/data_descriptors/standard_name/surface_downward_y_stress_correction.json +++ b/data_descriptors/standard_name/surface_downward_y_stress_correction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downward_y_stress_correction", + "id": "surface_downward_y_stress_correction", "type": "standard_name", "name": "surface_downward_y_stress_correction", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Downward y\" indicates the ZY component of a tensor. A downward y stress is a downward flux of momentum, which accelerates the lower medium in the direction of increasing y and and the upper medium in the direction of decreasing y. A positive correction is downward i.e. added to the ocean.", diff --git a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air.json b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air.json index 62e3281b7..b0ed315e6 100644 --- a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_longwave_flux_in_air", + "id": "surface_downwelling_longwave_flux_in_air", "type": "standard_name", "name": "surface_downwelling_longwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky.json index 3666dde2e..5a50cc520 100644 --- a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky", + "id": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 3a0c0201e..f56048f9a 100644 --- a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index ae6ea6464..97ffbef53 100644 --- a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_downwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json index 5c1adb65a..f32fc13f6 100644 --- a/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", + "id": "surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", "type": "standard_name", "name": "surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions.", diff --git a/data_descriptors/standard_name/surface_downwelling_photon_flux_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photon_flux_in_sea_water.json index c9832e35a..4cd4e79b6 100644 --- a/data_descriptors/standard_name/surface_downwelling_photon_flux_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photon_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photon_flux_in_sea_water", + "id": "surface_downwelling_photon_flux_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photon_flux_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water.json index f27d899f9..f44b7068b 100644 --- a/data_descriptors/standard_name/surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water", + "id": "surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photon_flux_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_downwelling_photon_radiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photon_radiance_in_sea_water.json index 14268c33d..cab449028 100644 --- a/data_descriptors/standard_name/surface_downwelling_photon_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photon_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photon_radiance_in_sea_water", + "id": "surface_downwelling_photon_radiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photon_radiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json index b616161e9..3a218c38e 100644 --- a/data_descriptors/standard_name/surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water", + "id": "surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photon_radiance_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_in_sea_water.json index 67198e76c..98ba88ae8 100644 --- a/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photon_spherical_irradiance_in_sea_water", + "id": "surface_downwelling_photon_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photon_spherical_irradiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or \"2-pi\") collector. The direction (\"up/downwelling\") is specified. Radiation incident on a 4-pi collector has a standard name referring to \"omnidirectional spherical irradiance\". A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json index 16ba8baa9..b369ffdb9 100644 --- a/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water", + "id": "surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photon_spherical_irradiance_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or \"2-pi\") collector. The direction (\"up/downwelling\") is specified. Radiation incident on a 4-pi collector has a standard name referring to \"omnidirectional spherical irradiance\". A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_air.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_air.json index 6030952b0..9d1f1aee6 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_photon_flux_in_air", + "id": "surface_downwelling_photosynthetic_photon_flux_in_air", "type": "standard_name", "name": "surface_downwelling_photosynthetic_photon_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_sea_water.json index 250ef9397..4996c8079 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_photon_flux_in_sea_water", + "id": "surface_downwelling_photosynthetic_photon_flux_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photosynthetic_photon_flux_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_radiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_radiance_in_sea_water.json index 0b70f9c2f..2d8368d38 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_photon_radiance_in_sea_water", + "id": "surface_downwelling_photosynthetic_photon_radiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photosynthetic_photon_radiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json index 2c0dcf74a..0200f80fc 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water", + "id": "surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or \"2-pi\") collector. The direction (\"up/downwelling\") is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\". A photon flux is specified in terms of numbers of photons expressed in moles.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiance_in_sea_water.json index d992da1b0..95a515a52 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_radiance_in_sea_water", + "id": "surface_downwelling_photosynthetic_radiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photosynthetic_radiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_air.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_air.json index 61c0a399d..efca952f8 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_radiative_flux_in_air", + "id": "surface_downwelling_photosynthetic_radiative_flux_in_air", "type": "standard_name", "name": "surface_downwelling_photosynthetic_radiative_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_sea_water.json index c72864545..a5ec9799d 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_radiative_flux_in_sea_water", + "id": "surface_downwelling_photosynthetic_radiative_flux_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photosynthetic_radiative_flux_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water.json index 8c7f1d8e3..85fc93190 100644 --- a/data_descriptors/standard_name/surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water", + "id": "surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Spherical irradiance is the radiation incident on unit area of a hemispherical (or \"2-pi\") collector. It is sometimes called \"scalar irradiance\". The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\".", diff --git a/data_descriptors/standard_name/surface_downwelling_radiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_radiance_in_sea_water.json index fb25f8208..341ae5d08 100644 --- a/data_descriptors/standard_name/surface_downwelling_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_radiance_in_sea_water", + "id": "surface_downwelling_radiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_radiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/surface_downwelling_radiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_radiance_per_unit_wavelength_in_sea_water.json index 05f357dc3..f38a987d4 100644 --- a/data_descriptors/standard_name/surface_downwelling_radiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_radiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_radiance_per_unit_wavelength_in_sea_water", + "id": "surface_downwelling_radiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_downwelling_radiance_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_downwelling_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_radiative_flux_in_sea_water.json index 8960dec3b..0522e553f 100644 --- a/data_descriptors/standard_name/surface_downwelling_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_radiative_flux_in_sea_water", + "id": "surface_downwelling_radiative_flux_in_sea_water", "type": "standard_name", "name": "surface_downwelling_radiative_flux_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_air.json index 863c89219..d5bfe3e0f 100644 --- a/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_air", + "id": "surface_downwelling_radiative_flux_per_unit_wavelength_in_air", "type": "standard_name", "name": "surface_downwelling_radiative_flux_per_unit_wavelength_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json index 27d4daff3..9b9cf64f7 100644 --- a/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water", + "id": "surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_downwelling_radiative_flux_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air.json index 3b186af62..7d9b99c4b 100644 --- a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_shortwave_flux_in_air", + "id": "surface_downwelling_shortwave_flux_in_air", "type": "standard_name", "name": "surface_downwelling_shortwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. Surface downwelling shortwave is the sum of direct and diffuse solar radiation incident on the surface, and is sometimes called \"global radiation\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky.json index dd0389793..73ab665dd 100644 --- a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", + "id": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. Surface downwelling shortwave is the sum of direct and diffuse solar radiation incident on the surface, and is sometimes called \"global radiation\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json index 8efe3bc0b..ab43c7ed1 100644 --- a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json +++ b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", + "id": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "type": "standard_name", "name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. Surface downwelling shortwave is the sum of direct and diffuse solar radiation incident on the surface, and is sometimes called \"global radiation\". When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index e2fd2f4db..ab3a26b4a 100644 --- a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index bebd76d7e..0164d0999 100644 --- a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_downwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json index 1c284355b..66e6d0305 100644 --- a/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", + "id": "surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", "type": "standard_name", "name": "surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions.", diff --git a/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_in_sea_water.json index 4fc4fb162..2e719cd17 100644 --- a/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_spherical_irradiance_in_sea_water", + "id": "surface_downwelling_spherical_irradiance_in_sea_water", "type": "standard_name", "name": "surface_downwelling_spherical_irradiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Spherical irradiance is the radiation incident on unit area of a hemispherical (or \"2-pi\") collector. It is sometimes called \"scalar irradiance\". The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\".", diff --git a/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json index d6399c8da..218af56f9 100644 --- a/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water", + "id": "surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_downwelling_spherical_irradiance_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Spherical irradiance is the radiation incident on unit area of a hemispherical (or \"2-pi\") collector. It is sometimes called \"scalar irradiance\". The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of \"omnidirectional spherical irradiance\". A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_drag_coefficient_for_heat_in_air.json b/data_descriptors/standard_name/surface_drag_coefficient_for_heat_in_air.json index 5754322e2..1a78e0161 100644 --- a/data_descriptors/standard_name/surface_drag_coefficient_for_heat_in_air.json +++ b/data_descriptors/standard_name/surface_drag_coefficient_for_heat_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_drag_coefficient_for_heat_in_air", + "id": "surface_drag_coefficient_for_heat_in_air", "type": "standard_name", "name": "surface_drag_coefficient_for_heat_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_drag_coefficient_for_momentum_in_air.json b/data_descriptors/standard_name/surface_drag_coefficient_for_momentum_in_air.json index 9cf237b62..376227310 100644 --- a/data_descriptors/standard_name/surface_drag_coefficient_for_momentum_in_air.json +++ b/data_descriptors/standard_name/surface_drag_coefficient_for_momentum_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_drag_coefficient_for_momentum_in_air", + "id": "surface_drag_coefficient_for_momentum_in_air", "type": "standard_name", "name": "surface_drag_coefficient_for_momentum_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_drag_coefficient_in_air.json b/data_descriptors/standard_name/surface_drag_coefficient_in_air.json index 67eca2fef..657865510 100644 --- a/data_descriptors/standard_name/surface_drag_coefficient_in_air.json +++ b/data_descriptors/standard_name/surface_drag_coefficient_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_drag_coefficient_in_air", + "id": "surface_drag_coefficient_in_air", "type": "standard_name", "name": "surface_drag_coefficient_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_eastward_sea_water_velocity.json b/data_descriptors/standard_name/surface_eastward_sea_water_velocity.json index f94b67b1d..eec98d69e 100644 --- a/data_descriptors/standard_name/surface_eastward_sea_water_velocity.json +++ b/data_descriptors/standard_name/surface_eastward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_eastward_sea_water_velocity", + "id": "surface_eastward_sea_water_velocity", "type": "standard_name", "name": "surface_eastward_sea_water_velocity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward).", diff --git a/data_descriptors/standard_name/surface_frozen_carbon_dioxide_amount.json b/data_descriptors/standard_name/surface_frozen_carbon_dioxide_amount.json index 84c449650..a9077f56b 100644 --- a/data_descriptors/standard_name/surface_frozen_carbon_dioxide_amount.json +++ b/data_descriptors/standard_name/surface_frozen_carbon_dioxide_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_frozen_carbon_dioxide_amount", + "id": "surface_frozen_carbon_dioxide_amount", "type": "standard_name", "name": "surface_frozen_carbon_dioxide_amount", "description": "\"Amount\" means mass per unit area. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. Frozen carbon dioxide is found on the surface of Mars.", diff --git a/data_descriptors/standard_name/surface_geopotential.json b/data_descriptors/standard_name/surface_geopotential.json index 1e23101c0..7ee44d3be 100644 --- a/data_descriptors/standard_name/surface_geopotential.json +++ b/data_descriptors/standard_name/surface_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geopotential", + "id": "surface_geopotential", "type": "standard_name", "name": "surface_geopotential", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy.", diff --git a/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity.json b/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity.json index 9ee521701..1586fe790 100644 --- a/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity.json +++ b/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_eastward_sea_water_velocity", + "id": "surface_geostrophic_eastward_sea_water_velocity", "type": "standard_name", "name": "surface_geostrophic_eastward_sea_water_velocity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. The quantity with standard name surface_geostrophic_eastward_sea_water_velocity is the sum of a variable part, surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.", diff --git a/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json b/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json index 4fa24271f..1119f39d0 100644 --- a/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json +++ b/data_descriptors/standard_name/surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid", + "id": "surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid", "type": "standard_name", "name": "surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean.) In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. The quantity with standard name surface_geostrophic_eastward_sea_water_velocity_assuming_mean_sea_level_for_geoid is the variable part of surface_geostrophic_eastward_sea_water_velocity. The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.", diff --git a/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity.json b/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity.json index c26272395..27893e756 100644 --- a/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity.json +++ b/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_northward_sea_water_velocity", + "id": "surface_geostrophic_northward_sea_water_velocity", "type": "standard_name", "name": "surface_geostrophic_northward_sea_water_velocity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. The quantity with standard name surface_geostrophic_northward_sea_water_velocity is the sum of a variable part, surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.", diff --git a/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json b/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json index 39166aa55..4eccfa166 100644 --- a/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json +++ b/data_descriptors/standard_name/surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid", + "id": "surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid", "type": "standard_name", "name": "surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean.) In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. The quantity with standard name surface_geostrophic_northward_sea_water_velocity_assuming_mean_sea_level_for_geoid is the variable part of surface_geostrophic_northward_sea_water_velocity. The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.", diff --git a/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity.json b/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity.json index 7842419f7..a48b2f516 100644 --- a/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity.json +++ b/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_sea_water_x_velocity", + "id": "surface_geostrophic_sea_water_x_velocity", "type": "standard_name", "name": "surface_geostrophic_sea_water_x_velocity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. The quantity with standard name surface_geostrophic_sea_water_x_velocity is the sum of a variable part, surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.", diff --git a/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid.json b/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid.json index b3da45339..06242816d 100644 --- a/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid.json +++ b/data_descriptors/standard_name/surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid", + "id": "surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid", "type": "standard_name", "name": "surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean.) In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. The quantity with standard name surface_geostrophic_sea_water_x_velocity_assuming_mean_sea_level_for_geoid is the variable part of surface_geostrophic_sea_water_x_velocity. The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.", diff --git a/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity.json b/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity.json index 3e2c19b0e..f458f2a50 100644 --- a/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity.json +++ b/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_sea_water_y_velocity", + "id": "surface_geostrophic_sea_water_y_velocity", "type": "standard_name", "name": "surface_geostrophic_sea_water_y_velocity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. The quantity with standard name surface_geostrophic_sea_water_y_velocity is the sum of a variable part, surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.", diff --git a/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid.json b/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid.json index 149069e8d..f83efd54a 100644 --- a/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid.json +++ b/data_descriptors/standard_name/surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid", + "id": "surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid", "type": "standard_name", "name": "surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Geostrophic\" indicates that geostrophic balance is assumed, i.e. that the pressure gradient force and the Coriolis force are balanced and the large scale fluid flow is parallel to the isobars. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean). In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. The quantity with standard name surface_geostrophic_sea_water_y_velocity_assuming_mean_sea_level_for_geoid is the variable part of surface_geostrophic_sea_water_y_velocity. The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.", diff --git a/data_descriptors/standard_name/surface_height_above_geopotential_datum.json b/data_descriptors/standard_name/surface_height_above_geopotential_datum.json index 87ef6a237..6c247ef55 100644 --- a/data_descriptors/standard_name/surface_height_above_geopotential_datum.json +++ b/data_descriptors/standard_name/surface_height_above_geopotential_datum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_height_above_geopotential_datum", + "id": "surface_height_above_geopotential_datum", "type": "standard_name", "name": "surface_height_above_geopotential_datum", "description": "\"Height_above_X\" means the vertical distance above the named surface X. The surface called \"surface\" means the lower boundary of the atmosphere. The \"geopotential datum\" is any estimated surface of constant geopotential used as a datum i.e. a reference level; for the geoid as a datum, specific standard names are available. To specify which geoid or geopotential datum is being used as a reference level, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", diff --git a/data_descriptors/standard_name/surface_litter_mass_content_of_carbon.json b/data_descriptors/standard_name/surface_litter_mass_content_of_carbon.json index 3e8734b56..67759c3f3 100644 --- a/data_descriptors/standard_name/surface_litter_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/surface_litter_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_litter_mass_content_of_carbon", + "id": "surface_litter_mass_content_of_carbon", "type": "standard_name", "name": "surface_litter_mass_content_of_carbon", "description": "\"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. \"Surface litter\" means the part of the litter resting above the soil surface. \"Content\" indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", diff --git a/data_descriptors/standard_name/surface_litter_mass_content_of_nitrogen.json b/data_descriptors/standard_name/surface_litter_mass_content_of_nitrogen.json index 46cf20f8e..25c7ec5ae 100644 --- a/data_descriptors/standard_name/surface_litter_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/surface_litter_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_litter_mass_content_of_nitrogen", + "id": "surface_litter_mass_content_of_nitrogen", "type": "standard_name", "name": "surface_litter_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent. \"Surface litter\" means the part of the litter resting above the soil surface. The sum of the quantities with standard names wood_debris_mass_content_of_nitrogen, surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen is the total nitrogen mass content of dead plant material.", diff --git a/data_descriptors/standard_name/surface_longwave_emissivity.json b/data_descriptors/standard_name/surface_longwave_emissivity.json index 707c71016..58c092e1c 100644 --- a/data_descriptors/standard_name/surface_longwave_emissivity.json +++ b/data_descriptors/standard_name/surface_longwave_emissivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_longwave_emissivity", + "id": "surface_longwave_emissivity", "type": "standard_name", "name": "surface_longwave_emissivity", "description": "Emissivity is the ratio of the power emitted by an object to the power that would be emitted by a perfect black body having the same temperature as the object. The emissivity is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength or radiation_frequency is included to specify either the wavelength or frequency. The surface called \"surface\" means the lower boundary of the atmosphere. \"longwave\" means longwave radiation.", diff --git a/data_descriptors/standard_name/surface_microwave_emissivity.json b/data_descriptors/standard_name/surface_microwave_emissivity.json index f04bfc63d..31ee7abc3 100644 --- a/data_descriptors/standard_name/surface_microwave_emissivity.json +++ b/data_descriptors/standard_name/surface_microwave_emissivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_microwave_emissivity", + "id": "surface_microwave_emissivity", "type": "standard_name", "name": "surface_microwave_emissivity", "description": "Emissivity is the ratio of the power emitted by an object to the power that would be emitted by a perfect black body having the same temperature as the object. The emissivity is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength or radiation_frequency is included to specify either the wavelength or frequency. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air.json b/data_descriptors/standard_name/surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air.json index 780a6f689..76f5b793d 100644 --- a/data_descriptors/standard_name/surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air.json +++ b/data_descriptors/standard_name/surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air", + "id": "surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air", "type": "standard_name", "name": "surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for molecular oxygen is O2. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", diff --git a/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect.json b/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect.json index a0336d446..0bc07052f 100644 --- a/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect.json +++ b/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect", + "id": "surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect", "type": "standard_name", "name": "surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). The term \"longwave\" means longwave radiation. \"X_direct_radiative_effect\" refers to the instantaneous radiative impact of X on the Earth's energy balance, excluding secondary effects such as changes in cloud cover which may be caused by X. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json b/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json index e25714178..0b26e8e16 100644 --- a/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", + "id": "surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "type": "standard_name", "name": "surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). The term \"longwave\" means longwave radiation. \"X_direct_radiative_effect\" refers to the instantaneous radiative impact of X on the Earth's energy balance, excluding secondary effects such as changes in cloud cover which may be caused by X. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_net_downward_longwave_flux.json b/data_descriptors/standard_name/surface_net_downward_longwave_flux.json index cf5575a1b..e0fb7d8e9 100644 --- a/data_descriptors/standard_name/surface_net_downward_longwave_flux.json +++ b/data_descriptors/standard_name/surface_net_downward_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_longwave_flux", + "id": "surface_net_downward_longwave_flux", "type": "standard_name", "name": "surface_net_downward_longwave_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"longwave\" means longwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_net_downward_longwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/surface_net_downward_longwave_flux_assuming_clear_sky.json index 24a853c78..c10db551b 100644 --- a/data_descriptors/standard_name/surface_net_downward_longwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_net_downward_longwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_longwave_flux_assuming_clear_sky", + "id": "surface_net_downward_longwave_flux_assuming_clear_sky", "type": "standard_name", "name": "surface_net_downward_longwave_flux_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange.json b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange.json index 841d9eab3..a6ca070d0 100644 --- a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange.json +++ b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange", + "id": "surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange", "type": "standard_name", "name": "surface_net_downward_mass_flux_of_ammonia_due_to_bidirectional_surface_exchange", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward mass flux is the difference between downward_mass_flux and upward_mass_flux. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Bidirectional surface exchange\" is the exchange of a chemical species between the atmosphere and biosphere as simulated by bidirectional surface flux models. It refers to exchange through stomata and soil surfaces and is the net result of emission and dry deposition. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes.json b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes.json index 2eac8a896..350cc0ff8 100644 --- a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes.json +++ b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes", + "id": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes", "type": "standard_name", "name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"All land processes\" means plant and soil respiration, photosynthesis, animal grazing, crop harvesting, natural fires and anthropogenic land use change. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes.json b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes.json index 9dbe86fd7..40890ebf3 100644 --- a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes.json +++ b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes", + "id": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes", "type": "standard_name", "name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"All land processes\" means plant and soil respiration, photosynthesis, animal grazing, crop harvesting, natural fires and anthropogenic land use change. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes.json b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes.json index 29e8734ae..7ba8bd2a6 100644 --- a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes.json +++ b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes", + "id": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes", "type": "standard_name", "name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"All land processes\" means plant and soil respiration, photosynthesis, animal grazing, crop harvesting, natural fires and anthropogenic land use change. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction. The quantity with standard name surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes is equal to the difference between the quantities with standard names surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change and surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change.json b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change.json index 731001bb2..51bed5d24 100644 --- a/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change.json +++ b/data_descriptors/standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change", + "id": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change", "type": "standard_name", "name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change", "description": "\"Downward\" indicates a vector component which is positive when directed downward (negative upward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"All land processes\" means plant and soil respiration, photosynthesis, animal grazing, crop harvesting, natural fires and anthropogenic land use change. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction. The quantity with standard name surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes is equal to the difference between the quantities with standard names surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change and surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_net_downward_radiative_flux.json b/data_descriptors/standard_name/surface_net_downward_radiative_flux.json index bcf3dd418..d076add6b 100644 --- a/data_descriptors/standard_name/surface_net_downward_radiative_flux.json +++ b/data_descriptors/standard_name/surface_net_downward_radiative_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_radiative_flux", + "id": "surface_net_downward_radiative_flux", "type": "standard_name", "name": "surface_net_downward_radiative_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", diff --git a/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect.json b/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect.json index 5144c97e4..8653723be 100644 --- a/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect.json +++ b/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect", + "id": "surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect", "type": "standard_name", "name": "surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The term \"shortwave\" means shortwave radiation. \"X_direct_radiative_effect\" refers to the instantaneous radiative impact of X on the Earth's energy balance, excluding secondary effects such as changes in cloud cover which may be caused by X. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json b/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json index 767f97f8b..f541b6a0b 100644 --- a/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", + "id": "surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "type": "standard_name", "name": "surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The term \"shortwave\" means shortwave radiation. \"X_direct_radiative_effect\" refers to the instantaneous radiative impact of X on the Earth's energy balance, excluding secondary effects such as changes in cloud cover which may be caused by X. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_net_downward_shortwave_flux.json b/data_descriptors/standard_name/surface_net_downward_shortwave_flux.json index 1c2d1f846..ded4f7887 100644 --- a/data_descriptors/standard_name/surface_net_downward_shortwave_flux.json +++ b/data_descriptors/standard_name/surface_net_downward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_shortwave_flux", + "id": "surface_net_downward_shortwave_flux", "type": "standard_name", "name": "surface_net_downward_shortwave_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"shortwave\" means shortwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_net_downward_shortwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/surface_net_downward_shortwave_flux_assuming_clear_sky.json index 11bc21279..6ec837a23 100644 --- a/data_descriptors/standard_name/surface_net_downward_shortwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_net_downward_shortwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_downward_shortwave_flux_assuming_clear_sky", + "id": "surface_net_downward_shortwave_flux_assuming_clear_sky", "type": "standard_name", "name": "surface_net_downward_shortwave_flux_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"shortwave\" means shortwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_net_upward_longwave_flux.json b/data_descriptors/standard_name/surface_net_upward_longwave_flux.json index 8f104b9d4..6e1aa25fc 100644 --- a/data_descriptors/standard_name/surface_net_upward_longwave_flux.json +++ b/data_descriptors/standard_name/surface_net_upward_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_upward_longwave_flux", + "id": "surface_net_upward_longwave_flux", "type": "standard_name", "name": "surface_net_upward_longwave_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"longwave\" means longwave radiation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change.json b/data_descriptors/standard_name/surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change.json index 7268cf371..9a68616e9 100644 --- a/data_descriptors/standard_name/surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change.json +++ b/data_descriptors/standard_name/surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change", + "id": "surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change", "type": "standard_name", "name": "surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction. The quantity with standard name surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes is equal to the difference between the quantities with standard names surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change and surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes.json b/data_descriptors/standard_name/surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes.json index 753cee887..116ca93e4 100644 --- a/data_descriptors/standard_name/surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes.json +++ b/data_descriptors/standard_name/surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes", + "id": "surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes", "type": "standard_name", "name": "surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). A net upward flux is the difference between the flux from below (upward) and the flux from above (downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Wetlands are areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season. The precise conditions under which wetlands produce and consume methane can vary between models. The quantity with standard name surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes is the difference between the upward and downward surface fluxes of methane which have standard names surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production and surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption, respectively.", diff --git a/data_descriptors/standard_name/surface_net_upward_radiative_flux.json b/data_descriptors/standard_name/surface_net_upward_radiative_flux.json index aa2f8be76..7629751b1 100644 --- a/data_descriptors/standard_name/surface_net_upward_radiative_flux.json +++ b/data_descriptors/standard_name/surface_net_upward_radiative_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_upward_radiative_flux", + "id": "surface_net_upward_radiative_flux", "type": "standard_name", "name": "surface_net_upward_radiative_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_net_upward_shortwave_flux.json b/data_descriptors/standard_name/surface_net_upward_shortwave_flux.json index acaeacfe8..f83187d86 100644 --- a/data_descriptors/standard_name/surface_net_upward_shortwave_flux.json +++ b/data_descriptors/standard_name/surface_net_upward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_net_upward_shortwave_flux", + "id": "surface_net_upward_shortwave_flux", "type": "standard_name", "name": "surface_net_upward_shortwave_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"shortwave\" means shortwave radiation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_northward_sea_water_velocity.json b/data_descriptors/standard_name/surface_northward_sea_water_velocity.json index 65f6ac17d..ee9194144 100644 --- a/data_descriptors/standard_name/surface_northward_sea_water_velocity.json +++ b/data_descriptors/standard_name/surface_northward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_northward_sea_water_velocity", + "id": "surface_northward_sea_water_velocity", "type": "standard_name", "name": "surface_northward_sea_water_velocity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. A velocity is a vector quantity. \"Northward\" indicates a vector component which is positive when directed northward (negative southward).", diff --git a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water.json b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water.json index 4ffa40ec2..0df98e9ed 100644 --- a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water.json +++ b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water", + "id": "surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water", "type": "standard_name", "name": "surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water", "description": "The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, an \"abiotic analogue\" is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged.", diff --git a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_air.json b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_air.json index 2ca17ae9b..9542a9b69 100644 --- a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_air.json +++ b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_partial_pressure_of_carbon_dioxide_in_air", + "id": "surface_partial_pressure_of_carbon_dioxide_in_air", "type": "standard_name", "name": "surface_partial_pressure_of_carbon_dioxide_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_sea_water.json b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_sea_water.json index 43d099f49..36b6a3079 100644 --- a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_sea_water.json +++ b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_partial_pressure_of_carbon_dioxide_in_sea_water", + "id": "surface_partial_pressure_of_carbon_dioxide_in_sea_water", "type": "standard_name", "name": "surface_partial_pressure_of_carbon_dioxide_in_sea_water", "description": "The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water.json b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water.json index a8f7c253f..7f80653c7 100644 --- a/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water.json +++ b/data_descriptors/standard_name/surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water", + "id": "surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water", "type": "standard_name", "name": "surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water", "description": "The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, a \"natural analogue\" is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content.json b/data_descriptors/standard_name/surface_radioactivity_content.json index f5e85e6c2..b5d0b5bab 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content.json +++ b/data_descriptors/standard_name/surface_radioactivity_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content", + "id": "surface_radioactivity_content", "type": "standard_name", "name": "surface_radioactivity_content", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_101Mo.json b/data_descriptors/standard_name/surface_radioactivity_content_of_101Mo.json index 084479396..52d78e9b7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_101Mo.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_101Mo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_101Mo", + "id": "surface_radioactivity_content_of_101Mo", "type": "standard_name", "name": "surface_radioactivity_content_of_101Mo", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Mo\" means the element \"molybdenum\" and \"101Mo\" is the isotope \"molybdenum-101\" with a half-life of 1.01e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_101Tc.json b/data_descriptors/standard_name/surface_radioactivity_content_of_101Tc.json index 944114e8c..c0f130ff6 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_101Tc.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_101Tc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_101Tc", + "id": "surface_radioactivity_content_of_101Tc", "type": "standard_name", "name": "surface_radioactivity_content_of_101Tc", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tc\" means the element \"technetium\" and \"101Tc\" is the isotope \"technetium-101\" with a half-life of 9.86e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_102Mo.json b/data_descriptors/standard_name/surface_radioactivity_content_of_102Mo.json index dac9bbdda..bed496331 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_102Mo.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_102Mo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_102Mo", + "id": "surface_radioactivity_content_of_102Mo", "type": "standard_name", "name": "surface_radioactivity_content_of_102Mo", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Mo\" means the element \"molybdenum\" and \"102Mo\" is the isotope \"molybdenum-102\" with a half-life of 7.71e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_102Tc.json b/data_descriptors/standard_name/surface_radioactivity_content_of_102Tc.json index 254212067..b298b6371 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_102Tc.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_102Tc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_102Tc", + "id": "surface_radioactivity_content_of_102Tc", "type": "standard_name", "name": "surface_radioactivity_content_of_102Tc", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tc\" means the element \"technetium\" and \"102Tc\" is the isotope \"technetium-102\" with a half-life of 6.12e-05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_102mTc.json b/data_descriptors/standard_name/surface_radioactivity_content_of_102mTc.json index a5dc7697e..aae5409c9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_102mTc.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_102mTc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_102mTc", + "id": "surface_radioactivity_content_of_102mTc", "type": "standard_name", "name": "surface_radioactivity_content_of_102mTc", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tc\" means the element \"technetium\" and \"102mTc\" is the metastable state of the isotope \"technetium-102\" with a half-life of 2.98e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_103Ru.json b/data_descriptors/standard_name/surface_radioactivity_content_of_103Ru.json index 710f79af6..bc21339eb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_103Ru.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_103Ru.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_103Ru", + "id": "surface_radioactivity_content_of_103Ru", "type": "standard_name", "name": "surface_radioactivity_content_of_103Ru", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ru\" means the element \"ruthenium\" and \"103Ru\" is the isotope \"ruthenium-103\" with a half-life of 3.95e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_103mRh.json b/data_descriptors/standard_name/surface_radioactivity_content_of_103mRh.json index eee3d7363..d980f43a8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_103mRh.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_103mRh.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_103mRh", + "id": "surface_radioactivity_content_of_103mRh", "type": "standard_name", "name": "surface_radioactivity_content_of_103mRh", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rh\" means the element \"rhodium\" and \"103mRh\" is the metastable state of the isotope \"rhodium-103\" with a half-life of 3.89e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_104Tc.json b/data_descriptors/standard_name/surface_radioactivity_content_of_104Tc.json index 01a5398cf..f0b265640 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_104Tc.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_104Tc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_104Tc", + "id": "surface_radioactivity_content_of_104Tc", "type": "standard_name", "name": "surface_radioactivity_content_of_104Tc", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tc\" means the element \"technetium\" and \"104Tc\" is the isotope \"technetium-104\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_105Rh.json b/data_descriptors/standard_name/surface_radioactivity_content_of_105Rh.json index 9daea7308..e67e75d4d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_105Rh.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_105Rh.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_105Rh", + "id": "surface_radioactivity_content_of_105Rh", "type": "standard_name", "name": "surface_radioactivity_content_of_105Rh", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rh\" means the element \"rhodium\" and \"105Rh\" is the isotope \"rhodium-105\" with a half-life of 1.48e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_105Ru.json b/data_descriptors/standard_name/surface_radioactivity_content_of_105Ru.json index 133511b15..3735968e4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_105Ru.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_105Ru.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_105Ru", + "id": "surface_radioactivity_content_of_105Ru", "type": "standard_name", "name": "surface_radioactivity_content_of_105Ru", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ru\" means the element \"ruthenium\" and \"105Ru\" is the isotope \"ruthenium-105\" with a half-life of 1.85e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_105mRh.json b/data_descriptors/standard_name/surface_radioactivity_content_of_105mRh.json index 89caf1c7f..54e688985 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_105mRh.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_105mRh.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_105mRh", + "id": "surface_radioactivity_content_of_105mRh", "type": "standard_name", "name": "surface_radioactivity_content_of_105mRh", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rh\" means the element \"rhodium\" and \"105mRh\" is the metastable state of the isotope \"rhodium-105\" with a half-life of 4.41e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_106Rh.json b/data_descriptors/standard_name/surface_radioactivity_content_of_106Rh.json index 357c285e9..b540d7876 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_106Rh.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_106Rh.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_106Rh", + "id": "surface_radioactivity_content_of_106Rh", "type": "standard_name", "name": "surface_radioactivity_content_of_106Rh", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rh\" means the element \"rhodium\" and \"106Rh\" is the isotope \"rhodium-106\" with a half-life of 3.46e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_106Ru.json b/data_descriptors/standard_name/surface_radioactivity_content_of_106Ru.json index a0cecb980..08c4937a2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_106Ru.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_106Ru.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_106Ru", + "id": "surface_radioactivity_content_of_106Ru", "type": "standard_name", "name": "surface_radioactivity_content_of_106Ru", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ru\" means the element \"ruthenium\" and \"106Ru\" is the isotope \"ruthenium-106\" with a half-life of 3.66e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_106mRh.json b/data_descriptors/standard_name/surface_radioactivity_content_of_106mRh.json index f1d98c80c..5d7a16a89 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_106mRh.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_106mRh.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_106mRh", + "id": "surface_radioactivity_content_of_106mRh", "type": "standard_name", "name": "surface_radioactivity_content_of_106mRh", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rh\" means the element \"rhodium\" and \"106mRh\" is the metastable state of the isotope \"rhodium-106\" with a half-life of 9.09e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_107Pd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_107Pd.json index 8adcfae0c..a41c24e5e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_107Pd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_107Pd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_107Pd", + "id": "surface_radioactivity_content_of_107Pd", "type": "standard_name", "name": "surface_radioactivity_content_of_107Pd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pd\" means the element \"palladium\" and \"107Pd\" is the isotope \"palladium-107\" with a half-life of 2.37e+09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_107Rh.json b/data_descriptors/standard_name/surface_radioactivity_content_of_107Rh.json index 0aade156e..df302ecf1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_107Rh.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_107Rh.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_107Rh", + "id": "surface_radioactivity_content_of_107Rh", "type": "standard_name", "name": "surface_radioactivity_content_of_107Rh", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rh\" means the element \"rhodium\" and \"107Rh\" is the isotope \"rhodium-107\" with a half-life of 1.51e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_107mPd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_107mPd.json index 5746e16ea..76c2cf5de 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_107mPd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_107mPd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_107mPd", + "id": "surface_radioactivity_content_of_107mPd", "type": "standard_name", "name": "surface_radioactivity_content_of_107mPd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pd\" means the element \"palladium\" and \"107mPd\" is the metastable state of the isotope \"palladium-107\" with a half-life of 2.47e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_109Pd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_109Pd.json index 2abd53bd5..eb36c2e4d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_109Pd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_109Pd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_109Pd", + "id": "surface_radioactivity_content_of_109Pd", "type": "standard_name", "name": "surface_radioactivity_content_of_109Pd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pd\" means the element \"palladium\" and \"109Pd\" is the isotope \"palladium-109\" with a half-life of 5.61e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_109mAg.json b/data_descriptors/standard_name/surface_radioactivity_content_of_109mAg.json index 473ff0ccc..0fa870336 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_109mAg.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_109mAg.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_109mAg", + "id": "surface_radioactivity_content_of_109mAg", "type": "standard_name", "name": "surface_radioactivity_content_of_109mAg", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"109mAg\" is the metastable state of the isotope \"silver-109\" with a half-life of 4.58e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_110mAg.json b/data_descriptors/standard_name/surface_radioactivity_content_of_110mAg.json index 04705329e..94f764bc2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_110mAg.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_110mAg.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_110mAg", + "id": "surface_radioactivity_content_of_110mAg", "type": "standard_name", "name": "surface_radioactivity_content_of_110mAg", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"110mAg\" is the metastable state of the isotope \"silver-110\" with a half-life of 2.70e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_111Ag.json b/data_descriptors/standard_name/surface_radioactivity_content_of_111Ag.json index 84123dd2f..4738d2243 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_111Ag.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_111Ag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_111Ag", + "id": "surface_radioactivity_content_of_111Ag", "type": "standard_name", "name": "surface_radioactivity_content_of_111Ag", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"111Ag\" is the isotope \"silver-111\" with a half-life of 7.50e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_111Pd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_111Pd.json index bf6350603..6d8d1888c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_111Pd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_111Pd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_111Pd", + "id": "surface_radioactivity_content_of_111Pd", "type": "standard_name", "name": "surface_radioactivity_content_of_111Pd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pd\" means the element \"palladium\" and \"111Pd\" is the isotope \"palladium-111\" with a half-life of 1.53e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_111mAg.json b/data_descriptors/standard_name/surface_radioactivity_content_of_111mAg.json index ca2f0e003..62840d14c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_111mAg.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_111mAg.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_111mAg", + "id": "surface_radioactivity_content_of_111mAg", "type": "standard_name", "name": "surface_radioactivity_content_of_111mAg", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"111mAg\" is the metastable state of the isotope \"silver-111\" with a half-life of 8.56e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_111mCd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_111mCd.json index 6f21f3431..c5c709770 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_111mCd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_111mCd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_111mCd", + "id": "surface_radioactivity_content_of_111mCd", "type": "standard_name", "name": "surface_radioactivity_content_of_111mCd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"111mCd\" is the metastable state of the isotope \"cadmium-111\" with a half-life of 3.39e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_111mPd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_111mPd.json index b8c7a3344..dcb9ebe8a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_111mPd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_111mPd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_111mPd", + "id": "surface_radioactivity_content_of_111mPd", "type": "standard_name", "name": "surface_radioactivity_content_of_111mPd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pd\" means the element \"palladium\" and \"111mPd\" is the metastable state of the isotope \"palladium-111\" with a half-life of 2.29e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_112Ag.json b/data_descriptors/standard_name/surface_radioactivity_content_of_112Ag.json index e51da4839..702204c32 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_112Ag.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_112Ag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_112Ag", + "id": "surface_radioactivity_content_of_112Ag", "type": "standard_name", "name": "surface_radioactivity_content_of_112Ag", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"112Ag\" is the isotope \"silver-112\" with a half-life of 1.30e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_112Pd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_112Pd.json index b3fe9837d..364cc0e21 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_112Pd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_112Pd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_112Pd", + "id": "surface_radioactivity_content_of_112Pd", "type": "standard_name", "name": "surface_radioactivity_content_of_112Pd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pd\" means the element \"palladium\" and \"112Pd\" is the isotope \"palladium-112\" with a half-life of 8.37e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_113Ag.json b/data_descriptors/standard_name/surface_radioactivity_content_of_113Ag.json index 035c9200a..f237ab17e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_113Ag.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_113Ag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_113Ag", + "id": "surface_radioactivity_content_of_113Ag", "type": "standard_name", "name": "surface_radioactivity_content_of_113Ag", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"113Ag\" is the isotope \"silver-113\" with a half-life of 2.21e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_113Cd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_113Cd.json index 1048b0175..fba4fc8ad 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_113Cd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_113Cd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_113Cd", + "id": "surface_radioactivity_content_of_113Cd", "type": "standard_name", "name": "surface_radioactivity_content_of_113Cd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"113Cd\" is the isotope \"cadmium-113\" with a half-life of 3.29e+18 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_113mAg.json b/data_descriptors/standard_name/surface_radioactivity_content_of_113mAg.json index 217d94e00..5cb25fc9e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_113mAg.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_113mAg.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_113mAg", + "id": "surface_radioactivity_content_of_113mAg", "type": "standard_name", "name": "surface_radioactivity_content_of_113mAg", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"113mAg\" is the metastable state of the isotope \"silver-113\" with a half-life of 7.64e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_113mCd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_113mCd.json index 7c76493d2..31ca75408 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_113mCd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_113mCd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_113mCd", + "id": "surface_radioactivity_content_of_113mCd", "type": "standard_name", "name": "surface_radioactivity_content_of_113mCd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"113mCd\" is the metastable state of the isotope \"cadmium-113\" with a half-life of 5.31e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_113mIn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_113mIn.json index 10e710de9..2deef8fb0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_113mIn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_113mIn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_113mIn", + "id": "surface_radioactivity_content_of_113mIn", "type": "standard_name", "name": "surface_radioactivity_content_of_113mIn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"113mIn\" is the metastable state of the isotope \"indium-113\" with a half-life of 6.92e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_115Ag.json b/data_descriptors/standard_name/surface_radioactivity_content_of_115Ag.json index 1ee2a5a93..d2706c959 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_115Ag.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_115Ag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_115Ag", + "id": "surface_radioactivity_content_of_115Ag", "type": "standard_name", "name": "surface_radioactivity_content_of_115Ag", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"115Ag\" is the isotope \"silver-115\" with a half-life of 1.46e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_115Cd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_115Cd.json index 4670fdab2..aca82d4c1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_115Cd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_115Cd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_115Cd", + "id": "surface_radioactivity_content_of_115Cd", "type": "standard_name", "name": "surface_radioactivity_content_of_115Cd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"115Cd\" is the isotope \"cadmium-115\" with a half-life of 2.23e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_115In.json b/data_descriptors/standard_name/surface_radioactivity_content_of_115In.json index 593af133f..16f5ee3e2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_115In.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_115In.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_115In", + "id": "surface_radioactivity_content_of_115In", "type": "standard_name", "name": "surface_radioactivity_content_of_115In", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"115In\" is the isotope \"indium-115\" with a half-life of 1.86e+18 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_115mAg.json b/data_descriptors/standard_name/surface_radioactivity_content_of_115mAg.json index 6697af0b6..b452fe6e4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_115mAg.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_115mAg.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_115mAg", + "id": "surface_radioactivity_content_of_115mAg", "type": "standard_name", "name": "surface_radioactivity_content_of_115mAg", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ag\" means the element \"silver\" and \"115mAg\" is the metastable state of the isotope \"silver-115\" with a half-life of 1.97e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_115mCd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_115mCd.json index 2a934d21a..7d984e5a1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_115mCd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_115mCd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_115mCd", + "id": "surface_radioactivity_content_of_115mCd", "type": "standard_name", "name": "surface_radioactivity_content_of_115mCd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"115mCd\" is the metastable state of the isotope \"cadmium-115\" with a half-life of 4.46e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_115mIn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_115mIn.json index 232a921ee..12933b06e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_115mIn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_115mIn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_115mIn", + "id": "surface_radioactivity_content_of_115mIn", "type": "standard_name", "name": "surface_radioactivity_content_of_115mIn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"115mIn\" is the metastable state of the isotope \"indium-115\" with a half-life of 1.87e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_116In.json b/data_descriptors/standard_name/surface_radioactivity_content_of_116In.json index 51a1e738e..488800ded 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_116In.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_116In.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_116In", + "id": "surface_radioactivity_content_of_116In", "type": "standard_name", "name": "surface_radioactivity_content_of_116In", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"116In\" is the isotope \"indium-116\" with a half-life of 1.64e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_116mIn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_116mIn.json index bccc501c6..8bb293c76 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_116mIn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_116mIn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_116mIn", + "id": "surface_radioactivity_content_of_116mIn", "type": "standard_name", "name": "surface_radioactivity_content_of_116mIn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"116mIn\" is the metastable state of the isotope \"indium-116\" with a half-life of 3.77e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_117Cd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_117Cd.json index c593ffe38..f42ec696b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_117Cd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_117Cd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_117Cd", + "id": "surface_radioactivity_content_of_117Cd", "type": "standard_name", "name": "surface_radioactivity_content_of_117Cd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"117Cd\" is the isotope \"cadmium-117\" with a half-life of 1.08e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_117In.json b/data_descriptors/standard_name/surface_radioactivity_content_of_117In.json index 92c7997e5..5a6a8c3ed 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_117In.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_117In.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_117In", + "id": "surface_radioactivity_content_of_117In", "type": "standard_name", "name": "surface_radioactivity_content_of_117In", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"117In\" is the isotope \"indium-117\" with a half-life of 3.05e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_117mCd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_117mCd.json index 753270fe2..c0ef48fc5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_117mCd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_117mCd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_117mCd", + "id": "surface_radioactivity_content_of_117mCd", "type": "standard_name", "name": "surface_radioactivity_content_of_117mCd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"117mCd\" is the metastable state of the isotope \"cadmium-117\" with a half-life of 1.42e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_117mIn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_117mIn.json index 827c9d67e..a38d5490f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_117mIn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_117mIn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_117mIn", + "id": "surface_radioactivity_content_of_117mIn", "type": "standard_name", "name": "surface_radioactivity_content_of_117mIn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"117mIn\" is the metastable state of the isotope \"indium-117\" with a half-life of 8.08e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_117mSn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_117mSn.json index 4784ee0bb..281326c73 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_117mSn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_117mSn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_117mSn", + "id": "surface_radioactivity_content_of_117mSn", "type": "standard_name", "name": "surface_radioactivity_content_of_117mSn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"117mSn\" is the metastable state of the isotope \"tin-117\" with a half-life of 1.40e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_118Cd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_118Cd.json index 21cb9370c..32a623dfb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_118Cd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_118Cd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_118Cd", + "id": "surface_radioactivity_content_of_118Cd", "type": "standard_name", "name": "surface_radioactivity_content_of_118Cd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cd\" means the element \"cadmium\" and \"118Cd\" is the isotope \"cadmium-118\" with a half-life of 3.49e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_118In.json b/data_descriptors/standard_name/surface_radioactivity_content_of_118In.json index 19e6713bf..891912d52 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_118In.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_118In.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_118In", + "id": "surface_radioactivity_content_of_118In", "type": "standard_name", "name": "surface_radioactivity_content_of_118In", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"118In\" is the isotope \"indium-118\" with a half-life of 5.77e-05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_118mIn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_118mIn.json index 47f657ee5..7181099e7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_118mIn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_118mIn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_118mIn", + "id": "surface_radioactivity_content_of_118mIn", "type": "standard_name", "name": "surface_radioactivity_content_of_118mIn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"118mIn\" is the metastable state of the isotope \"indium-118\" with a half-life of 3.05e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_119In.json b/data_descriptors/standard_name/surface_radioactivity_content_of_119In.json index d2261f154..83bc22f22 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_119In.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_119In.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_119In", + "id": "surface_radioactivity_content_of_119In", "type": "standard_name", "name": "surface_radioactivity_content_of_119In", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"119In\" is the isotope \"indium-119\" with a half-life of 1.74e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_119mIn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_119mIn.json index 98dbc5575..7d04692f2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_119mIn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_119mIn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_119mIn", + "id": "surface_radioactivity_content_of_119mIn", "type": "standard_name", "name": "surface_radioactivity_content_of_119mIn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"In\" means the element \"indium\" and \"119mIn\" is the metastable state of the isotope \"indium-119\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_119mSn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_119mSn.json index 7a573d345..5beee3ffd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_119mSn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_119mSn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_119mSn", + "id": "surface_radioactivity_content_of_119mSn", "type": "standard_name", "name": "surface_radioactivity_content_of_119mSn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"119mSn\" is the metastable state of the isotope \"tin-119\" with a half-life of 2.45e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_11C.json b/data_descriptors/standard_name/surface_radioactivity_content_of_11C.json index 0e6577a8a..4329788de 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_11C.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_11C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_11C", + "id": "surface_radioactivity_content_of_11C", "type": "standard_name", "name": "surface_radioactivity_content_of_11C", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"C\" means the element \"carbon\" and \"11C\" is the isotope \"carbon-11\" with a half-life of 1.41e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_121Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_121Sn.json index 714bf0b73..8e4b7899d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_121Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_121Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_121Sn", + "id": "surface_radioactivity_content_of_121Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_121Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"121Sn\" is the isotope \"tin-121\" with a half-life of 1.12e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_121mSn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_121mSn.json index 8312b67e6..42e154cdc 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_121mSn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_121mSn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_121mSn", + "id": "surface_radioactivity_content_of_121mSn", "type": "standard_name", "name": "surface_radioactivity_content_of_121mSn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"121mSn\" is the metastable state of the isotope \"tin-121\" with a half-life of 1.82e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_123Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_123Sn.json index dc66d0afe..05f13b75f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_123Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_123Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_123Sn", + "id": "surface_radioactivity_content_of_123Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_123Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"123Sn\" is the isotope \"tin-123\" with a half-life of 1.29e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_123mSn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_123mSn.json index 06921afd2..37193ea5e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_123mSn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_123mSn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_123mSn", + "id": "surface_radioactivity_content_of_123mSn", "type": "standard_name", "name": "surface_radioactivity_content_of_123mSn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"123mSn\" is the metastable state of the isotope \"tin-123\" with a half-life of 2.78e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_124Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_124Sb.json index 4a1ffba05..ad569f43c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_124Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_124Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_124Sb", + "id": "surface_radioactivity_content_of_124Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_124Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"124Sb\" is the isotope \"antimony-124\" with a half-life of 6.03e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_124mSb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_124mSb.json index 30a57d62c..a53ecceee 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_124mSb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_124mSb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_124mSb", + "id": "surface_radioactivity_content_of_124mSb", "type": "standard_name", "name": "surface_radioactivity_content_of_124mSb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"124mSb\" is the metastable state of the isotope \"antimony-124\" with a half-life of 1.41e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_125Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_125Sb.json index c6970901c..89aa5c990 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_125Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_125Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_125Sb", + "id": "surface_radioactivity_content_of_125Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_125Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"125Sb\" is the isotope \"antimony-125\" with a half-life of 9.97e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_125Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_125Sn.json index baeb24996..1d9d1b0aa 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_125Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_125Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_125Sn", + "id": "surface_radioactivity_content_of_125Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_125Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"125Sn\" is the isotope \"tin-125\" with a half-life of 9.65e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_125mTe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_125mTe.json index bad691e15..64625f1b1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_125mTe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_125mTe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_125mTe", + "id": "surface_radioactivity_content_of_125mTe", "type": "standard_name", "name": "surface_radioactivity_content_of_125mTe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"125mTe\" is the metastable state of the isotope \"tellurium-125\" with a half-life of 5.81e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_126Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_126Sb.json index 9330f2a33..0f2d25119 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_126Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_126Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_126Sb", + "id": "surface_radioactivity_content_of_126Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_126Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"126Sb\" is the isotope \"antimony-126\" with a half-life of 1.24e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_126Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_126Sn.json index e82403172..9a1eb03fd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_126Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_126Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_126Sn", + "id": "surface_radioactivity_content_of_126Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_126Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"126Sn\" is the isotope \"tin-126\" with a half-life of 3.65e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_126mSb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_126mSb.json index 194a7d560..67897f833 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_126mSb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_126mSb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_126mSb", + "id": "surface_radioactivity_content_of_126mSb", "type": "standard_name", "name": "surface_radioactivity_content_of_126mSb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"126mSb\" is the metastable state of the isotope \"antimony-126\" with a half-life of 1.32e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_127Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_127Sb.json index d7fa01b46..8d7cfe18c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_127Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_127Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_127Sb", + "id": "surface_radioactivity_content_of_127Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_127Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"127Sb\" is the isotope \"antimony-127\" with a half-life of 3.80e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_127Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_127Sn.json index 59455226a..e9d20d19f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_127Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_127Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_127Sn", + "id": "surface_radioactivity_content_of_127Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_127Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"127Sn\" is the isotope \"tin-127\" with a half-life of 8.84e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_127Te.json b/data_descriptors/standard_name/surface_radioactivity_content_of_127Te.json index 041ee8f4f..e924430c7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_127Te.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_127Te.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_127Te", + "id": "surface_radioactivity_content_of_127Te", "type": "standard_name", "name": "surface_radioactivity_content_of_127Te", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"127Te\" is the isotope \"tellurium-127\" with a half-life of 3.91e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_127mTe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_127mTe.json index ab6812f52..e331893ff 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_127mTe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_127mTe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_127mTe", + "id": "surface_radioactivity_content_of_127mTe", "type": "standard_name", "name": "surface_radioactivity_content_of_127mTe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"127mTe\" is the metastable state of the isotope \"tellurium-127\" with a half-life of 1.09e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_128Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_128Sb.json index d7f3f2b3e..a4d2736a6 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_128Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_128Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_128Sb", + "id": "surface_radioactivity_content_of_128Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_128Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"128Sb\" is the isotope \"antimony-128\" with a half-life of 3.75e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_128Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_128Sn.json index e1b588d91..1ba8edd26 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_128Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_128Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_128Sn", + "id": "surface_radioactivity_content_of_128Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_128Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"128Sn\" is the isotope \"tin-128\" with a half-life of 4.09e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_128mSb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_128mSb.json index c2524f01f..9c009072b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_128mSb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_128mSb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_128mSb", + "id": "surface_radioactivity_content_of_128mSb", "type": "standard_name", "name": "surface_radioactivity_content_of_128mSb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"128mSb\" is the metastable state of the isotope \"antimony-128\" with a half-life of 7.23e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_129I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_129I.json index 7377d8ae0..6ffeee629 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_129I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_129I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_129I", + "id": "surface_radioactivity_content_of_129I", "type": "standard_name", "name": "surface_radioactivity_content_of_129I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"129I\" is the isotope \"iodine-129\" with a half-life of 5.81e+09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_129Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_129Sb.json index 38b6845d4..d652f4b72 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_129Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_129Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_129Sb", + "id": "surface_radioactivity_content_of_129Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_129Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"129Sb\" is the isotope \"antimony-129\" with a half-life of 1.81e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_129Te.json b/data_descriptors/standard_name/surface_radioactivity_content_of_129Te.json index de66484b2..589006fbb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_129Te.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_129Te.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_129Te", + "id": "surface_radioactivity_content_of_129Te", "type": "standard_name", "name": "surface_radioactivity_content_of_129Te", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"129Te\" is the isotope \"tellurium-129\" with a half-life of 4.86e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_129mTe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_129mTe.json index c458896ed..1768ed104 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_129mTe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_129mTe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_129mTe", + "id": "surface_radioactivity_content_of_129mTe", "type": "standard_name", "name": "surface_radioactivity_content_of_129mTe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"129mTe\" is the metastable state of the isotope \"tellurium-129\" with a half-life of 3.34e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_129mXe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_129mXe.json index c55aee968..751ad9b93 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_129mXe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_129mXe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_129mXe", + "id": "surface_radioactivity_content_of_129mXe", "type": "standard_name", "name": "surface_radioactivity_content_of_129mXe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"129mXe\" is the metastable state of the isotope \"xenon-129\" with a half-life of 8.02e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_130I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_130I.json index d2f087dc5..1efe06e91 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_130I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_130I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_130I", + "id": "surface_radioactivity_content_of_130I", "type": "standard_name", "name": "surface_radioactivity_content_of_130I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"130I\" is the isotope \"iodine-130\" with a half-life of 5.18e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_130Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_130Sb.json index 86ba1112d..d0fed6dde 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_130Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_130Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_130Sb", + "id": "surface_radioactivity_content_of_130Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_130Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"130Sb\" is the isotope \"antimony-130\" with a half-life of 2.57e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_130Sn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_130Sn.json index 2e90e5943..5895755bf 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_130Sn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_130Sn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_130Sn", + "id": "surface_radioactivity_content_of_130Sn", "type": "standard_name", "name": "surface_radioactivity_content_of_130Sn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sn\" means the element \"tin\" and \"130Sn\" is the isotope \"tin-130\" with a half-life of 2.57e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_130mI.json b/data_descriptors/standard_name/surface_radioactivity_content_of_130mI.json index 26dc996d3..aebaa218b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_130mI.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_130mI.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_130mI", + "id": "surface_radioactivity_content_of_130mI", "type": "standard_name", "name": "surface_radioactivity_content_of_130mI", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"130mI\" is the metastable state of the isotope \"iodine-130\" with a half-life of 6.17e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_130mSb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_130mSb.json index 75935960e..74bd63d15 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_130mSb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_130mSb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_130mSb", + "id": "surface_radioactivity_content_of_130mSb", "type": "standard_name", "name": "surface_radioactivity_content_of_130mSb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"130mSb\" is the metastable state of the isotope \"antimony-130\" with a half-life of 4.58e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_131I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_131I.json index 50abe0450..b01879bc9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_131I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_131I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_131I", + "id": "surface_radioactivity_content_of_131I", "type": "standard_name", "name": "surface_radioactivity_content_of_131I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"131I\" is the isotope \"iodine-131\" with a half-life of 8.07e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_131Sb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_131Sb.json index d2a1ecbcb..130a667f2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_131Sb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_131Sb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_131Sb", + "id": "surface_radioactivity_content_of_131Sb", "type": "standard_name", "name": "surface_radioactivity_content_of_131Sb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sb\" means the element \"antimony\" and \"131Sb\" is the isotope \"antimony-131\" with a half-life of 1.60e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_131Te.json b/data_descriptors/standard_name/surface_radioactivity_content_of_131Te.json index 07ae83647..e34fd7f42 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_131Te.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_131Te.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_131Te", + "id": "surface_radioactivity_content_of_131Te", "type": "standard_name", "name": "surface_radioactivity_content_of_131Te", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"131Te\" is the isotope \"tellurium-131\" with a half-life of 1.74e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_131mTe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_131mTe.json index 301d0de15..791c15256 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_131mTe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_131mTe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_131mTe", + "id": "surface_radioactivity_content_of_131mTe", "type": "standard_name", "name": "surface_radioactivity_content_of_131mTe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"131mTe\" is the metastable state of the isotope \"tellurium-131\" with a half-life of 1.25e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_131mXe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_131mXe.json index 8e73f43cd..b4c001b4b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_131mXe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_131mXe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_131mXe", + "id": "surface_radioactivity_content_of_131mXe", "type": "standard_name", "name": "surface_radioactivity_content_of_131mXe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"131mXe\" is the metastable state of the isotope \"xenon-131\" with a half-life of 1.18e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_132I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_132I.json index 6aa9cf856..b003bd37d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_132I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_132I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_132I", + "id": "surface_radioactivity_content_of_132I", "type": "standard_name", "name": "surface_radioactivity_content_of_132I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"132I\" is the isotope \"iodine-132\" with a half-life of 9.60e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_132Te.json b/data_descriptors/standard_name/surface_radioactivity_content_of_132Te.json index 6fe9635d6..67494d866 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_132Te.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_132Te.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_132Te", + "id": "surface_radioactivity_content_of_132Te", "type": "standard_name", "name": "surface_radioactivity_content_of_132Te", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"132Te\" is the isotope \"tellurium-132\" with a half-life of 3.25e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_133I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_133I.json index 272263133..eef41ee09 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_133I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_133I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_133I", + "id": "surface_radioactivity_content_of_133I", "type": "standard_name", "name": "surface_radioactivity_content_of_133I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"133I\" is the isotope \"iodine-133\" with a half-life of 8.71e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_133Te.json b/data_descriptors/standard_name/surface_radioactivity_content_of_133Te.json index b48d46c7d..26ddc6124 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_133Te.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_133Te.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_133Te", + "id": "surface_radioactivity_content_of_133Te", "type": "standard_name", "name": "surface_radioactivity_content_of_133Te", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"133Te\" is the isotope \"tellurium-133\" with a half-life of 8.68e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_133Xe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_133Xe.json index bffad435b..9b72e3cbb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_133Xe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_133Xe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_133Xe", + "id": "surface_radioactivity_content_of_133Xe", "type": "standard_name", "name": "surface_radioactivity_content_of_133Xe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"133Xe\" is the isotope \"xenon-133\" with a half-life of 5.28e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_133mI.json b/data_descriptors/standard_name/surface_radioactivity_content_of_133mI.json index c2c46c985..9614a8fec 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_133mI.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_133mI.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_133mI", + "id": "surface_radioactivity_content_of_133mI", "type": "standard_name", "name": "surface_radioactivity_content_of_133mI", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"133mI\" is the metastable state of the isotope \"iodine-133\" with a half-life of 1.04e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_133mTe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_133mTe.json index e3f23420d..06692ae9c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_133mTe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_133mTe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_133mTe", + "id": "surface_radioactivity_content_of_133mTe", "type": "standard_name", "name": "surface_radioactivity_content_of_133mTe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"133mTe\" is the metastable state of the isotope \"tellurium-133\" with a half-life of 3.84e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_133mXe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_133mXe.json index 381e6b353..d1a491b6b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_133mXe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_133mXe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_133mXe", + "id": "surface_radioactivity_content_of_133mXe", "type": "standard_name", "name": "surface_radioactivity_content_of_133mXe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"133mXe\" is the metastable state of the isotope \"xenon-133\" with a half-life of 2.26e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_134Cs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_134Cs.json index 745ba3a98..34d757255 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_134Cs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_134Cs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_134Cs", + "id": "surface_radioactivity_content_of_134Cs", "type": "standard_name", "name": "surface_radioactivity_content_of_134Cs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"134Cs\" is the isotope \"cesium-134\" with a half-life of 7.50e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_134I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_134I.json index 456724f0a..b39c7b272 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_134I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_134I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_134I", + "id": "surface_radioactivity_content_of_134I", "type": "standard_name", "name": "surface_radioactivity_content_of_134I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"134I\" is the isotope \"iodine-134\" with a half-life of 3.61e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_134Te.json b/data_descriptors/standard_name/surface_radioactivity_content_of_134Te.json index 7b82f12c8..7e7b88bdd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_134Te.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_134Te.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_134Te", + "id": "surface_radioactivity_content_of_134Te", "type": "standard_name", "name": "surface_radioactivity_content_of_134Te", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Te\" means the element \"tellurium\" and \"134Te\" is the isotope \"tellurium-134\" with a half-life of 2.92e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_134mCs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_134mCs.json index b236c0368..18fe5d902 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_134mCs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_134mCs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_134mCs", + "id": "surface_radioactivity_content_of_134mCs", "type": "standard_name", "name": "surface_radioactivity_content_of_134mCs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"134mCs\" is the metastable state of the isotope \"cesium-134\" with a half-life of 1.21e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_134mI.json b/data_descriptors/standard_name/surface_radioactivity_content_of_134mI.json index 30cbb812a..28cbcfc50 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_134mI.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_134mI.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_134mI", + "id": "surface_radioactivity_content_of_134mI", "type": "standard_name", "name": "surface_radioactivity_content_of_134mI", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"134mI\" is the metastable state of the isotope \"iodine-134\" with a half-life of 2.50e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_134mXe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_134mXe.json index 67cae6c8d..e83366723 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_134mXe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_134mXe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_134mXe", + "id": "surface_radioactivity_content_of_134mXe", "type": "standard_name", "name": "surface_radioactivity_content_of_134mXe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"134mXe\" is the metastable state of the isotope \"xenon-134\" with a half-life of 3.36e-06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_135Cs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_135Cs.json index 038b641e1..837e6d312 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_135Cs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_135Cs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_135Cs", + "id": "surface_radioactivity_content_of_135Cs", "type": "standard_name", "name": "surface_radioactivity_content_of_135Cs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"135Cs\" is the isotope \"cesium-135\" with a half-life of 8.39e+08 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_135I.json b/data_descriptors/standard_name/surface_radioactivity_content_of_135I.json index 954c54558..0551b7a23 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_135I.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_135I.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_135I", + "id": "surface_radioactivity_content_of_135I", "type": "standard_name", "name": "surface_radioactivity_content_of_135I", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"I\" means the element \"iodine\" and \"135I\" is the isotope \"iodine-135\" with a half-life of 2.79e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_135Xe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_135Xe.json index bd4608a5a..b79608a64 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_135Xe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_135Xe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_135Xe", + "id": "surface_radioactivity_content_of_135Xe", "type": "standard_name", "name": "surface_radioactivity_content_of_135Xe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"135Xe\" is the isotope \"xenon-135\" with a half-life of 3.82e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_135mBa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_135mBa.json index a91dacea7..d35b111d2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_135mBa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_135mBa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_135mBa", + "id": "surface_radioactivity_content_of_135mBa", "type": "standard_name", "name": "surface_radioactivity_content_of_135mBa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ba\" means the element \"barium\" and \"135mBa\" is the metastable state of the isotope \"barium-135\" with a half-life of 1.20e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_135mCs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_135mCs.json index 01f9a08cf..3d1f1d568 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_135mCs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_135mCs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_135mCs", + "id": "surface_radioactivity_content_of_135mCs", "type": "standard_name", "name": "surface_radioactivity_content_of_135mCs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"135mCs\" is the metastable state of the isotope \"cesium-135\" with a half-life of 3.68e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_135mXe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_135mXe.json index d09976a66..431bdba56 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_135mXe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_135mXe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_135mXe", + "id": "surface_radioactivity_content_of_135mXe", "type": "standard_name", "name": "surface_radioactivity_content_of_135mXe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"135mXe\" is the metastable state of the isotope \"xenon-135\" with a half-life of 1.08e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_136Cs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_136Cs.json index 97ffb6667..4d31a63f1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_136Cs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_136Cs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_136Cs", + "id": "surface_radioactivity_content_of_136Cs", "type": "standard_name", "name": "surface_radioactivity_content_of_136Cs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"136Cs\" is the isotope \"cesium-136\" with a half-life of 1.30e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_137Cs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_137Cs.json index a388861d7..9f3e74c56 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_137Cs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_137Cs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_137Cs", + "id": "surface_radioactivity_content_of_137Cs", "type": "standard_name", "name": "surface_radioactivity_content_of_137Cs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"137Cs\" is the isotope \"cesium-137\" with a half-life of 1.10e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_137Xe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_137Xe.json index 38ed5496b..640b68280 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_137Xe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_137Xe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_137Xe", + "id": "surface_radioactivity_content_of_137Xe", "type": "standard_name", "name": "surface_radioactivity_content_of_137Xe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"137Xe\" is the isotope \"xenon-137\" with a half-life of 2.71e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_137mBa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_137mBa.json index cc484d2ea..acdfd7f09 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_137mBa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_137mBa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_137mBa", + "id": "surface_radioactivity_content_of_137mBa", "type": "standard_name", "name": "surface_radioactivity_content_of_137mBa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ba\" means the element \"barium\" and \"137mBa\" is the metastable state of the isotope \"barium-137\" with a half-life of 1.77e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_138Cs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_138Cs.json index 702a131ac..dc18e8149 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_138Cs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_138Cs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_138Cs", + "id": "surface_radioactivity_content_of_138Cs", "type": "standard_name", "name": "surface_radioactivity_content_of_138Cs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cs\" means the element \"cesium\" and \"138Cs\" is the isotope \"cesium-138\" with a half-life of 2.23e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_138Xe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_138Xe.json index b243691ac..1b6f496df 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_138Xe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_138Xe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_138Xe", + "id": "surface_radioactivity_content_of_138Xe", "type": "standard_name", "name": "surface_radioactivity_content_of_138Xe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Xe\" means the element \"xenon\" and \"138Xe\" is the isotope \"xenon-138\" with a half-life of 9.84e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_139Ba.json b/data_descriptors/standard_name/surface_radioactivity_content_of_139Ba.json index 9a897d0e3..67f7f8074 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_139Ba.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_139Ba.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_139Ba", + "id": "surface_radioactivity_content_of_139Ba", "type": "standard_name", "name": "surface_radioactivity_content_of_139Ba", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ba\" means the element \"barium\" and \"139Ba\" is the isotope \"barium-139\" with a half-life of 5.77e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_13N.json b/data_descriptors/standard_name/surface_radioactivity_content_of_13N.json index 3ba7f9aff..40c659da4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_13N.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_13N.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_13N", + "id": "surface_radioactivity_content_of_13N", "type": "standard_name", "name": "surface_radioactivity_content_of_13N", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"N\" means the element \"nitrogen\" and \"13N\" is the isotope \"nitrogen-13\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_140Ba.json b/data_descriptors/standard_name/surface_radioactivity_content_of_140Ba.json index eb6605cf5..c24f594ec 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_140Ba.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_140Ba.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_140Ba", + "id": "surface_radioactivity_content_of_140Ba", "type": "standard_name", "name": "surface_radioactivity_content_of_140Ba", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ba\" means the element \"barium\" and \"140Ba\" is the isotope \"barium-140\" with a half-life of 1.28e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_140La.json b/data_descriptors/standard_name/surface_radioactivity_content_of_140La.json index 668cddf2a..e6ce6d716 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_140La.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_140La.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_140La", + "id": "surface_radioactivity_content_of_140La", "type": "standard_name", "name": "surface_radioactivity_content_of_140La", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"La\" means the element \"lanthanum\" and \"140La\" is the isotope \"lanthanum-140\" with a half-life of 1.76e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_141Ce.json b/data_descriptors/standard_name/surface_radioactivity_content_of_141Ce.json index ed1d0e373..99ae19dc8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_141Ce.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_141Ce.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_141Ce", + "id": "surface_radioactivity_content_of_141Ce", "type": "standard_name", "name": "surface_radioactivity_content_of_141Ce", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ce\" means the element \"cerium\" and \"141Ce\" is the isotope \"cerium-141\" with a half-life of 3.30e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_141La.json b/data_descriptors/standard_name/surface_radioactivity_content_of_141La.json index 6abdedd87..6c7fc0a78 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_141La.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_141La.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_141La", + "id": "surface_radioactivity_content_of_141La", "type": "standard_name", "name": "surface_radioactivity_content_of_141La", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"La\" means the element \"lanthanum\" and \"141La\" is the isotope \"lanthanum-141\" with a half-life of 1.61e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_142Ce.json b/data_descriptors/standard_name/surface_radioactivity_content_of_142Ce.json index 39ae78c08..768d80681 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_142Ce.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_142Ce.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_142Ce", + "id": "surface_radioactivity_content_of_142Ce", "type": "standard_name", "name": "surface_radioactivity_content_of_142Ce", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ce\" means the element \"cerium\" and \"142Ce\" is the isotope \"cerium-142\" with a half-life of 1.82e+19 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_142La.json b/data_descriptors/standard_name/surface_radioactivity_content_of_142La.json index 76e8c02fe..58d60e18c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_142La.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_142La.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_142La", + "id": "surface_radioactivity_content_of_142La", "type": "standard_name", "name": "surface_radioactivity_content_of_142La", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"La\" means the element \"lanthanum\" and \"142La\" is the isotope \"lanthanum-142\" with a half-life of 6.42e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_142Pr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_142Pr.json index b8770306f..a76e6782c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_142Pr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_142Pr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_142Pr", + "id": "surface_radioactivity_content_of_142Pr", "type": "standard_name", "name": "surface_radioactivity_content_of_142Pr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"142Pr\" is the isotope \"praseodymium-142\" with a half-life of 7.94e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_142mPr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_142mPr.json index 1a6712293..f3224faf0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_142mPr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_142mPr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_142mPr", + "id": "surface_radioactivity_content_of_142mPr", "type": "standard_name", "name": "surface_radioactivity_content_of_142mPr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"142mPr\" is the metastable state of the isotope \"praseodymium-142\" with a half-life of 1.01e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_143Ce.json b/data_descriptors/standard_name/surface_radioactivity_content_of_143Ce.json index 04b4a1785..ab3d7c568 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_143Ce.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_143Ce.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_143Ce", + "id": "surface_radioactivity_content_of_143Ce", "type": "standard_name", "name": "surface_radioactivity_content_of_143Ce", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ce\" means the element \"cerium\" and \"143Ce\" is the isotope \"cerium-143\" with a half-life of 1.37e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_143La.json b/data_descriptors/standard_name/surface_radioactivity_content_of_143La.json index fcf57712e..80892fdd4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_143La.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_143La.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_143La", + "id": "surface_radioactivity_content_of_143La", "type": "standard_name", "name": "surface_radioactivity_content_of_143La", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"La\" means the element \"lanthanum\" and \"143La\" is the isotope \"lanthanum-143\" with a half-life of 9.72e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_143Pr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_143Pr.json index c453e958a..e73407cac 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_143Pr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_143Pr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_143Pr", + "id": "surface_radioactivity_content_of_143Pr", "type": "standard_name", "name": "surface_radioactivity_content_of_143Pr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"143Pr\" is the isotope \"praseodymium-143\" with a half-life of 1.36e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_144Ce.json b/data_descriptors/standard_name/surface_radioactivity_content_of_144Ce.json index 35be916e7..2aa75e2ee 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_144Ce.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_144Ce.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_144Ce", + "id": "surface_radioactivity_content_of_144Ce", "type": "standard_name", "name": "surface_radioactivity_content_of_144Ce", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ce\" means the element \"cerium\" and \"144Ce\" is the isotope \"cerium-144\" with a half-life of 2.84e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_144Nd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_144Nd.json index 47a2d40ac..25daab9aa 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_144Nd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_144Nd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_144Nd", + "id": "surface_radioactivity_content_of_144Nd", "type": "standard_name", "name": "surface_radioactivity_content_of_144Nd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nd\" means the element \"neodymium\" and \"144Nd\" is the isotope \"neodymium-144\" with a half-life of 7.64e+17 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_144Pr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_144Pr.json index 3e6f17057..7ca6788ae 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_144Pr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_144Pr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_144Pr", + "id": "surface_radioactivity_content_of_144Pr", "type": "standard_name", "name": "surface_radioactivity_content_of_144Pr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"144Pr\" is the isotope \"praseodymium-144\" with a half-life of 1.20e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_144mPr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_144mPr.json index 340b4f2fe..5fccfbde4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_144mPr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_144mPr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_144mPr", + "id": "surface_radioactivity_content_of_144mPr", "type": "standard_name", "name": "surface_radioactivity_content_of_144mPr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"144mPr\" is the metastable state of the isotope \"praseodymium-144\" with a half-life of 4.98e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_145Pr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_145Pr.json index e1c3bedac..dee43635f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_145Pr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_145Pr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_145Pr", + "id": "surface_radioactivity_content_of_145Pr", "type": "standard_name", "name": "surface_radioactivity_content_of_145Pr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"145Pr\" is the isotope \"praseodymium-145\" with a half-life of 2.49e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_146Ce.json b/data_descriptors/standard_name/surface_radioactivity_content_of_146Ce.json index 97ba0f97b..c46adaf8c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_146Ce.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_146Ce.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_146Ce", + "id": "surface_radioactivity_content_of_146Ce", "type": "standard_name", "name": "surface_radioactivity_content_of_146Ce", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ce\" means the element \"cerium\" and \"146Ce\" is the isotope \"cerium-146\" with a half-life of 9.86e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_146Pr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_146Pr.json index 6b9d94b5d..64ec01729 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_146Pr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_146Pr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_146Pr", + "id": "surface_radioactivity_content_of_146Pr", "type": "standard_name", "name": "surface_radioactivity_content_of_146Pr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"146Pr\" is the isotope \"praseodymium-146\" with a half-life of 1.68e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_147Nd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_147Nd.json index 3dd9a8fa5..9d06c5648 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_147Nd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_147Nd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_147Nd", + "id": "surface_radioactivity_content_of_147Nd", "type": "standard_name", "name": "surface_radioactivity_content_of_147Nd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nd\" means the element \"neodymium\" and \"147Nd\" is the isotope \"neodymium-147\" with a half-life of 1.10e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_147Pm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_147Pm.json index fae354fa7..73f278e00 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_147Pm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_147Pm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_147Pm", + "id": "surface_radioactivity_content_of_147Pm", "type": "standard_name", "name": "surface_radioactivity_content_of_147Pm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"147Pm\" is the isotope \"promethium-147\" with a half-life of 9.57e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_147Pr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_147Pr.json index b80303bad..3acce8d6a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_147Pr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_147Pr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_147Pr", + "id": "surface_radioactivity_content_of_147Pr", "type": "standard_name", "name": "surface_radioactivity_content_of_147Pr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pr\" means the element \"praseodymium\" and \"147Pr\" is the isotope \"praseodymium-147\" with a half-life of 8.33e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_147Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_147Sm.json index c03ba470e..6d4875402 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_147Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_147Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_147Sm", + "id": "surface_radioactivity_content_of_147Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_147Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"147Sm\" is the isotope \"samarium-147\" with a half-life of 3.91e+13 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_148Pm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_148Pm.json index 88ff89d4c..67fa5ae08 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_148Pm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_148Pm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_148Pm", + "id": "surface_radioactivity_content_of_148Pm", "type": "standard_name", "name": "surface_radioactivity_content_of_148Pm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"148Pm\" is the isotope \"promethium-148\" with a half-life of 5.38e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_148Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_148Sm.json index 03b3332f6..2f68858f9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_148Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_148Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_148Sm", + "id": "surface_radioactivity_content_of_148Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_148Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"148Sm\" is the isotope \"samarium-148\" with a half-life of 2.92e+18 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_148mPm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_148mPm.json index a8b7b29ca..d9a60cd2c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_148mPm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_148mPm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_148mPm", + "id": "surface_radioactivity_content_of_148mPm", "type": "standard_name", "name": "surface_radioactivity_content_of_148mPm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"148mPm\" is the metastable state of the isotope \"promethium-148\" with a half-life of 4.14e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_149Nd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_149Nd.json index 87b27010c..089d4558f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_149Nd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_149Nd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_149Nd", + "id": "surface_radioactivity_content_of_149Nd", "type": "standard_name", "name": "surface_radioactivity_content_of_149Nd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nd\" means the element \"neodymium\" and \"149Nd\" is the isotope \"neodymium-149\" with a half-life of 7.23e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_149Pm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_149Pm.json index 718da64b9..26753d4cf 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_149Pm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_149Pm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_149Pm", + "id": "surface_radioactivity_content_of_149Pm", "type": "standard_name", "name": "surface_radioactivity_content_of_149Pm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"149Pm\" is the isotope \"promethium-149\" with a half-life of 2.21e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_149Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_149Sm.json index 5ae4b154d..f131d5663 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_149Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_149Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_149Sm", + "id": "surface_radioactivity_content_of_149Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_149Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"149Sm\" is the isotope \"samarium-149\" with a half-life of 3.65e+18 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_150Pm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_150Pm.json index 091d84c2e..11b444a41 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_150Pm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_150Pm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_150Pm", + "id": "surface_radioactivity_content_of_150Pm", "type": "standard_name", "name": "surface_radioactivity_content_of_150Pm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"150Pm\" is the isotope \"promethium-150\" with a half-life of 1.12e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_151Nd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_151Nd.json index 1a3b52053..cb48fcb3b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_151Nd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_151Nd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_151Nd", + "id": "surface_radioactivity_content_of_151Nd", "type": "standard_name", "name": "surface_radioactivity_content_of_151Nd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nd\" means the element \"neodymium\" and \"151Nd\" is the isotope \"neodymium-151\" with a half-life of 8.61e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_151Pm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_151Pm.json index 124eae9e2..8ac2168de 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_151Pm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_151Pm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_151Pm", + "id": "surface_radioactivity_content_of_151Pm", "type": "standard_name", "name": "surface_radioactivity_content_of_151Pm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"151Pm\" is the isotope \"promethium-151\" with a half-life of 1.18e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_151Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_151Sm.json index 9ffbcd8c4..56b417c43 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_151Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_151Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_151Sm", + "id": "surface_radioactivity_content_of_151Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_151Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"151Sm\" is the isotope \"samarium-151\" with a half-life of 3.40e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_152Nd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_152Nd.json index 42fe51d14..68de17d8e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_152Nd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_152Nd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_152Nd", + "id": "surface_radioactivity_content_of_152Nd", "type": "standard_name", "name": "surface_radioactivity_content_of_152Nd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nd\" means the element \"neodymium\" and \"152Nd\" is the isotope \"neodymium-152\" with a half-life of 7.94e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_152Pm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_152Pm.json index 7ddf08c18..ed5f42b62 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_152Pm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_152Pm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_152Pm", + "id": "surface_radioactivity_content_of_152Pm", "type": "standard_name", "name": "surface_radioactivity_content_of_152Pm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"152Pm\" is the isotope \"promethium-152\" with a half-life of 2.84e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_152mPm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_152mPm.json index 8860f4ba5..c5cabd255 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_152mPm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_152mPm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_152mPm", + "id": "surface_radioactivity_content_of_152mPm", "type": "standard_name", "name": "surface_radioactivity_content_of_152mPm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pm\" means the element \"promethium\" and \"152mPm\" is the metastable state of the isotope \"promethium-152\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_153Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_153Sm.json index 6fed45fc1..6ef8a144d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_153Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_153Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_153Sm", + "id": "surface_radioactivity_content_of_153Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_153Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"153Sm\" is the isotope \"samarium-153\" with a half-life of 1.94e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_154Eu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_154Eu.json index 85c5bf01b..0050289bb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_154Eu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_154Eu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_154Eu", + "id": "surface_radioactivity_content_of_154Eu", "type": "standard_name", "name": "surface_radioactivity_content_of_154Eu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Eu\" means the element \"europium\" and \"154Eu\" is the isotope \"europium-154\" with a half-life of 3.13e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_155Eu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_155Eu.json index d76c74cb0..6b8d0f31c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_155Eu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_155Eu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_155Eu", + "id": "surface_radioactivity_content_of_155Eu", "type": "standard_name", "name": "surface_radioactivity_content_of_155Eu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Eu\" means the element \"europium\" and \"155Eu\" is the isotope \"europium-155\" with a half-life of 1.75e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_155Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_155Sm.json index 34566f39e..31fe16d33 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_155Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_155Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_155Sm", + "id": "surface_radioactivity_content_of_155Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_155Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"155Sm\" is the isotope \"samarium-155\" with a half-life of 1.54e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_156Eu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_156Eu.json index 98f849439..20c37959a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_156Eu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_156Eu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_156Eu", + "id": "surface_radioactivity_content_of_156Eu", "type": "standard_name", "name": "surface_radioactivity_content_of_156Eu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Eu\" means the element \"europium\" and \"156Eu\" is the isotope \"europium-156\" with a half-life of 1.52e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_156Sm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_156Sm.json index 92f9caf60..9f59adc1a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_156Sm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_156Sm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_156Sm", + "id": "surface_radioactivity_content_of_156Sm", "type": "standard_name", "name": "surface_radioactivity_content_of_156Sm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sm\" means the element \"samarium\" and \"156Sm\" is the isotope \"samarium-156\" with a half-life of 3.91e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_157Eu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_157Eu.json index b505402cd..8fbfc0b68 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_157Eu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_157Eu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_157Eu", + "id": "surface_radioactivity_content_of_157Eu", "type": "standard_name", "name": "surface_radioactivity_content_of_157Eu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Eu\" means the element \"europium\" and \"157Eu\" is the isotope \"europium-157\" with a half-life of 6.32e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_158Eu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_158Eu.json index 3a53210cd..1fa9e37b2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_158Eu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_158Eu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_158Eu", + "id": "surface_radioactivity_content_of_158Eu", "type": "standard_name", "name": "surface_radioactivity_content_of_158Eu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Eu\" means the element \"europium\" and \"158Eu\" is the isotope \"europium-158\" with a half-life of 3.18e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_159Eu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_159Eu.json index f9ec38f83..326c8263f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_159Eu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_159Eu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_159Eu", + "id": "surface_radioactivity_content_of_159Eu", "type": "standard_name", "name": "surface_radioactivity_content_of_159Eu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Eu\" means the element \"europium\" and \"159Eu\" is the isotope \"europium-159\" with a half-life of 1.26e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_159Gd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_159Gd.json index ba4246cca..f0ce29573 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_159Gd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_159Gd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_159Gd", + "id": "surface_radioactivity_content_of_159Gd", "type": "standard_name", "name": "surface_radioactivity_content_of_159Gd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Gd\" means the element \"gadolinium\" and \"159Gd\" is the isotope \"gadolinium-159\" with a half-life of 7.71e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_15O.json b/data_descriptors/standard_name/surface_radioactivity_content_of_15O.json index c61181fdf..1e879ec76 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_15O.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_15O.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_15O", + "id": "surface_radioactivity_content_of_15O", "type": "standard_name", "name": "surface_radioactivity_content_of_15O", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"O\" means the element \"oxygen\" and \"15O\" is the isotope \"oxygen-15\" with a half-life of 1.41e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_160Tb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_160Tb.json index 829993626..565c00186 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_160Tb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_160Tb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_160Tb", + "id": "surface_radioactivity_content_of_160Tb", "type": "standard_name", "name": "surface_radioactivity_content_of_160Tb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tb\" means the element \"terbium\" and \"160Tb\" is the isotope \"terbium-160\" with a half-life of 7.23e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_161Tb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_161Tb.json index b9ffc5fd8..8be26e8a1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_161Tb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_161Tb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_161Tb", + "id": "surface_radioactivity_content_of_161Tb", "type": "standard_name", "name": "surface_radioactivity_content_of_161Tb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tb\" means the element \"terbium\" and \"161Tb\" is the isotope \"terbium-161\" with a half-life of 6.92e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_162Gd.json b/data_descriptors/standard_name/surface_radioactivity_content_of_162Gd.json index 3b175370f..8fe0b4587 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_162Gd.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_162Gd.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_162Gd", + "id": "surface_radioactivity_content_of_162Gd", "type": "standard_name", "name": "surface_radioactivity_content_of_162Gd", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Gd\" means the element \"gadolinium\" and \"162Gd\" is the isotope \"gadolinium-162\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_162Tb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_162Tb.json index 785725005..341c61fcb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_162Tb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_162Tb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_162Tb", + "id": "surface_radioactivity_content_of_162Tb", "type": "standard_name", "name": "surface_radioactivity_content_of_162Tb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tb\" means the element \"terbium\" and \"162Tb\" is the isotope \"terbium-162\" with a half-life of 5.18e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_162mTb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_162mTb.json index 759223702..58e4d4441 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_162mTb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_162mTb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_162mTb", + "id": "surface_radioactivity_content_of_162mTb", "type": "standard_name", "name": "surface_radioactivity_content_of_162mTb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tb\" means the element \"terbium\" and \"162mTb\" is the metastable state of the isotope \"terbium-162\" with a half-life of 9.30e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_163Tb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_163Tb.json index c5ecaac85..e04c7ee54 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_163Tb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_163Tb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_163Tb", + "id": "surface_radioactivity_content_of_163Tb", "type": "standard_name", "name": "surface_radioactivity_content_of_163Tb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tb\" means the element \"terbium\" and \"163Tb\" is the isotope \"terbium-163\" with a half-life of 1.36e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_165Dy.json b/data_descriptors/standard_name/surface_radioactivity_content_of_165Dy.json index ddc4fdad5..c8bade333 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_165Dy.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_165Dy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_165Dy", + "id": "surface_radioactivity_content_of_165Dy", "type": "standard_name", "name": "surface_radioactivity_content_of_165Dy", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Dy\" means the element \"dysprosium\" and \"165Dy\" is the isotope \"dysprosium-165\" with a half-life of 9.80e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_18F.json b/data_descriptors/standard_name/surface_radioactivity_content_of_18F.json index b6a42f597..698b567f2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_18F.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_18F.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_18F", + "id": "surface_radioactivity_content_of_18F", "type": "standard_name", "name": "surface_radioactivity_content_of_18F", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"F\" means the element \"fluorine\" and \"18F\" is the isotope \"fluorine-18\" with a half-life of 6.98e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_206Hg.json b/data_descriptors/standard_name/surface_radioactivity_content_of_206Hg.json index 9ba6915cf..030f5781c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_206Hg.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_206Hg.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_206Hg", + "id": "surface_radioactivity_content_of_206Hg", "type": "standard_name", "name": "surface_radioactivity_content_of_206Hg", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Hg\" means the element \"mercury\" and \"206Hg\" is the isotope \"mercury-206\" with a half-life of 5.57e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_206Tl.json b/data_descriptors/standard_name/surface_radioactivity_content_of_206Tl.json index 82b15d450..219f8ff18 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_206Tl.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_206Tl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_206Tl", + "id": "surface_radioactivity_content_of_206Tl", "type": "standard_name", "name": "surface_radioactivity_content_of_206Tl", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tl\" means the element \"thallium\" and \"206Tl\" is the isotope \"thallium-206\" with a half-life of 2.91e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_207Tl.json b/data_descriptors/standard_name/surface_radioactivity_content_of_207Tl.json index 6039cfb10..e13a02227 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_207Tl.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_207Tl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_207Tl", + "id": "surface_radioactivity_content_of_207Tl", "type": "standard_name", "name": "surface_radioactivity_content_of_207Tl", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tl\" means the element \"thallium\" and \"207Tl\" is the isotope \"thallium-207\" with a half-life of 3.33e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_207mPb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_207mPb.json index 2ca873d59..2f134b3a8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_207mPb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_207mPb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_207mPb", + "id": "surface_radioactivity_content_of_207mPb", "type": "standard_name", "name": "surface_radioactivity_content_of_207mPb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"207mPb\" is the metastable state of the isotope \"lead-207\" with a half-life of 9.26e-06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_208Tl.json b/data_descriptors/standard_name/surface_radioactivity_content_of_208Tl.json index 788758fcf..3d83bb805 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_208Tl.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_208Tl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_208Tl", + "id": "surface_radioactivity_content_of_208Tl", "type": "standard_name", "name": "surface_radioactivity_content_of_208Tl", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tl\" means the element \"thallium\" and \"208Tl\" is the isotope \"thallium-208\" with a half-life of 2.15e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_209Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_209Bi.json index 4e64bcb8e..04ee9363b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_209Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_209Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_209Bi", + "id": "surface_radioactivity_content_of_209Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_209Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"209Bi\" is the isotope \"bismuth-209\" with a half-life of 7.29e+20 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_209Pb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_209Pb.json index ccb7a3aac..ae316034d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_209Pb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_209Pb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_209Pb", + "id": "surface_radioactivity_content_of_209Pb", "type": "standard_name", "name": "surface_radioactivity_content_of_209Pb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"209Pb\" is the isotope \"lead-209\" with a half-life of 1.38e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_209Tl.json b/data_descriptors/standard_name/surface_radioactivity_content_of_209Tl.json index 9324528e8..e400bb128 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_209Tl.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_209Tl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_209Tl", + "id": "surface_radioactivity_content_of_209Tl", "type": "standard_name", "name": "surface_radioactivity_content_of_209Tl", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tl\" means the element \"thallium\" and \"209Tl\" is the isotope \"thallium-209\" with a half-life of 1.53e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_210Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_210Bi.json index 2453a845f..21cc7eddc 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_210Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_210Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_210Bi", + "id": "surface_radioactivity_content_of_210Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_210Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"210Bi\" is the isotope \"bismuth-210\" with a half-life of 5.01e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_210Pb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_210Pb.json index 3fc670977..fe385fcbf 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_210Pb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_210Pb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_210Pb", + "id": "surface_radioactivity_content_of_210Pb", "type": "standard_name", "name": "surface_radioactivity_content_of_210Pb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"210Pb\" is the isotope \"lead-210\" with a half-life of 7.64e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_210Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_210Po.json index 3b20ddfe9..b0ba69c89 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_210Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_210Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_210Po", + "id": "surface_radioactivity_content_of_210Po", "type": "standard_name", "name": "surface_radioactivity_content_of_210Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"210Po\" is the isotope \"polonium-210\" with a half-life of 1.38e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_210Tl.json b/data_descriptors/standard_name/surface_radioactivity_content_of_210Tl.json index a99e414bd..ee6bffa1a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_210Tl.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_210Tl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_210Tl", + "id": "surface_radioactivity_content_of_210Tl", "type": "standard_name", "name": "surface_radioactivity_content_of_210Tl", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tl\" means the element \"thallium\" and \"210Tl\" is the isotope \"thallium-210\" with a half-life of 9.02e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_211Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_211Bi.json index 16d821c4a..a451fd4c9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_211Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_211Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_211Bi", + "id": "surface_radioactivity_content_of_211Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_211Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"211Bi\" is the isotope \"bismuth-211\" with a half-life of 1.49e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_211Pb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_211Pb.json index 93a052b0e..5315f803a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_211Pb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_211Pb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_211Pb", + "id": "surface_radioactivity_content_of_211Pb", "type": "standard_name", "name": "surface_radioactivity_content_of_211Pb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"211Pb\" is the isotope \"lead-211\" with a half-life of 2.51e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_211Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_211Po.json index 8d1c607f3..0c25c56c4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_211Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_211Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_211Po", + "id": "surface_radioactivity_content_of_211Po", "type": "standard_name", "name": "surface_radioactivity_content_of_211Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"211Po\" is the isotope \"polonium-211\" with a half-life of 6.03e-06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_212Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_212Bi.json index bb40c0ca7..e48d16eee 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_212Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_212Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_212Bi", + "id": "surface_radioactivity_content_of_212Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_212Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"212Bi\" is the isotope \"bismuth-212\" with a half-life of 4.20e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_212Pb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_212Pb.json index 664a6ec27..1bd0c99f2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_212Pb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_212Pb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_212Pb", + "id": "surface_radioactivity_content_of_212Pb", "type": "standard_name", "name": "surface_radioactivity_content_of_212Pb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"212Pb\" is the isotope \"lead-212\" with a half-life of 4.43e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_212Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_212Po.json index 33a81ed6e..696b7aa29 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_212Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_212Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_212Po", + "id": "surface_radioactivity_content_of_212Po", "type": "standard_name", "name": "surface_radioactivity_content_of_212Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"212Po\" is the isotope \"polonium-212\" with a half-life of 3.52e-12 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_213Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_213Bi.json index e85e1f9de..6272238ec 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_213Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_213Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_213Bi", + "id": "surface_radioactivity_content_of_213Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_213Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"213Bi\" is the isotope \"bismuth-213\" with a half-life of 3.26e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_213Pb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_213Pb.json index c2d326059..df64319da 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_213Pb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_213Pb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_213Pb", + "id": "surface_radioactivity_content_of_213Pb", "type": "standard_name", "name": "surface_radioactivity_content_of_213Pb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"213Pb\" is the isotope \"lead-213\" with a half-life of 6.92e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_213Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_213Po.json index 7e988ba6d..d94b447e1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_213Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_213Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_213Po", + "id": "surface_radioactivity_content_of_213Po", "type": "standard_name", "name": "surface_radioactivity_content_of_213Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"213Po\" is the isotope \"polonium-213\" with a half-life of 4.86e-11 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_214Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_214Bi.json index ec06eb1a6..7c29c1fa9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_214Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_214Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_214Bi", + "id": "surface_radioactivity_content_of_214Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_214Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"214Bi\" is the isotope \"bismuth-214\" with a half-life of 1.37e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_214Pb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_214Pb.json index cb146afe7..031f5b062 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_214Pb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_214Pb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_214Pb", + "id": "surface_radioactivity_content_of_214Pb", "type": "standard_name", "name": "surface_radioactivity_content_of_214Pb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pb\" means the element \"lead\" and \"214Pb\" is the isotope \"lead-214\" with a half-life of 1.86e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_214Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_214Po.json index aec9b84ee..3b92d5cd0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_214Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_214Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_214Po", + "id": "surface_radioactivity_content_of_214Po", "type": "standard_name", "name": "surface_radioactivity_content_of_214Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"214Po\" is the isotope \"polonium-214\" with a half-life of 1.90e-09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_215At.json b/data_descriptors/standard_name/surface_radioactivity_content_of_215At.json index a117b588a..9a257429d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_215At.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_215At.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_215At", + "id": "surface_radioactivity_content_of_215At", "type": "standard_name", "name": "surface_radioactivity_content_of_215At", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"At\" means the element \"astatine\" and \"215At\" is the isotope \"astatine-215\" with a half-life of 1.16e-09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_215Bi.json b/data_descriptors/standard_name/surface_radioactivity_content_of_215Bi.json index 54c3a81c0..6886be926 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_215Bi.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_215Bi.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_215Bi", + "id": "surface_radioactivity_content_of_215Bi", "type": "standard_name", "name": "surface_radioactivity_content_of_215Bi", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bi\" means the element \"bismuth\" and \"215Bi\" is the isotope \"bismuth-215\" with a half-life of 4.86e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_215Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_215Po.json index d78a6afe6..ec615642a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_215Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_215Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_215Po", + "id": "surface_radioactivity_content_of_215Po", "type": "standard_name", "name": "surface_radioactivity_content_of_215Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"215Po\" is the isotope \"polonium-215\" with a half-life of 2.06e-08 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_216At.json b/data_descriptors/standard_name/surface_radioactivity_content_of_216At.json index 2073bef8e..80b77f3a5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_216At.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_216At.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_216At", + "id": "surface_radioactivity_content_of_216At", "type": "standard_name", "name": "surface_radioactivity_content_of_216At", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"At\" means the element \"astatine\" and \"216At\" is the isotope \"astatine-216\" with a half-life of 3.47e-09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_216Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_216Po.json index 6c4700b91..d9b67afb5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_216Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_216Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_216Po", + "id": "surface_radioactivity_content_of_216Po", "type": "standard_name", "name": "surface_radioactivity_content_of_216Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"216Po\" is the isotope \"polonium-216\" with a half-life of 1.74e-06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_217At.json b/data_descriptors/standard_name/surface_radioactivity_content_of_217At.json index e5e074704..51c763e8f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_217At.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_217At.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_217At", + "id": "surface_radioactivity_content_of_217At", "type": "standard_name", "name": "surface_radioactivity_content_of_217At", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"At\" means the element \"astatine\" and \"217At\" is the isotope \"astatine-217\" with a half-life of 3.70e-07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_217Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_217Po.json index 965b2c870..6928c3efc 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_217Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_217Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_217Po", + "id": "surface_radioactivity_content_of_217Po", "type": "standard_name", "name": "surface_radioactivity_content_of_217Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"217Po\" is the isotope \"polonium-217\" with a half-life of 1.16e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_218At.json b/data_descriptors/standard_name/surface_radioactivity_content_of_218At.json index 1ad15fbc4..596197ff0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_218At.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_218At.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_218At", + "id": "surface_radioactivity_content_of_218At", "type": "standard_name", "name": "surface_radioactivity_content_of_218At", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"At\" means the element \"astatine\" and \"218At\" is the isotope \"astatine-218\" with a half-life of 2.31e-05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_218Po.json b/data_descriptors/standard_name/surface_radioactivity_content_of_218Po.json index 314a84a11..83f085942 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_218Po.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_218Po.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_218Po", + "id": "surface_radioactivity_content_of_218Po", "type": "standard_name", "name": "surface_radioactivity_content_of_218Po", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Po\" means the element \"polonium\" and \"218Po\" is the isotope \"polonium-218\" with a half-life of 2.12e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_218Rn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_218Rn.json index bd92444f5..21ae685c9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_218Rn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_218Rn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_218Rn", + "id": "surface_radioactivity_content_of_218Rn", "type": "standard_name", "name": "surface_radioactivity_content_of_218Rn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rn\" means the element \"radon\" and \"218Rn\" is the isotope \"radon-218\" with a half-life of 4.05e-07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_219At.json b/data_descriptors/standard_name/surface_radioactivity_content_of_219At.json index 276e207a1..c19ecc21e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_219At.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_219At.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_219At", + "id": "surface_radioactivity_content_of_219At", "type": "standard_name", "name": "surface_radioactivity_content_of_219At", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"At\" means the element \"astatine\" and \"219At\" is the isotope \"astatine-219\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_219Rn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_219Rn.json index f24fb8746..0c3067848 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_219Rn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_219Rn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_219Rn", + "id": "surface_radioactivity_content_of_219Rn", "type": "standard_name", "name": "surface_radioactivity_content_of_219Rn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rn\" means the element \"radon\" and \"219Rn\" is the isotope \"radon-219\" with a half-life of 4.64e-05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_220Rn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_220Rn.json index 30f19389c..e375667d0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_220Rn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_220Rn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_220Rn", + "id": "surface_radioactivity_content_of_220Rn", "type": "standard_name", "name": "surface_radioactivity_content_of_220Rn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rn\" means the element \"radon\" and \"220Rn\" is the isotope \"radon-220\" with a half-life of 6.37e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_221Fr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_221Fr.json index 2f0420e4b..4c9de5e0d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_221Fr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_221Fr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_221Fr", + "id": "surface_radioactivity_content_of_221Fr", "type": "standard_name", "name": "surface_radioactivity_content_of_221Fr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Fr\" means the element \"francium\" and \"221Fr\" is the isotope \"francium-221\" with a half-life of 3.33e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_221Rn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_221Rn.json index c5ee0039f..5df35ca9c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_221Rn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_221Rn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_221Rn", + "id": "surface_radioactivity_content_of_221Rn", "type": "standard_name", "name": "surface_radioactivity_content_of_221Rn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rn\" means the element \"radon\" and \"221Rn\" is the isotope \"radon-221\" with a half-life of 1.74e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_222Fr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_222Fr.json index 7579b3c0a..68705170d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_222Fr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_222Fr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_222Fr", + "id": "surface_radioactivity_content_of_222Fr", "type": "standard_name", "name": "surface_radioactivity_content_of_222Fr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Fr\" means the element \"francium\" and \"222Fr\" is the isotope \"francium-222\" with a half-life of 1.03e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_222Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_222Ra.json index f7e05776a..b2e9ddea5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_222Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_222Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_222Ra", + "id": "surface_radioactivity_content_of_222Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_222Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"222Ra\" is the isotope \"radium-222\" with a half-life of 4.41e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_222Rn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_222Rn.json index cbbeba655..808370cb4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_222Rn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_222Rn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_222Rn", + "id": "surface_radioactivity_content_of_222Rn", "type": "standard_name", "name": "surface_radioactivity_content_of_222Rn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rn\" means the element \"radon\" and \"222Rn\" is the isotope \"radon-222\" with a half-life of 3.82e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_223Fr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_223Fr.json index f3d7a374d..ad0a2f5f8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_223Fr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_223Fr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_223Fr", + "id": "surface_radioactivity_content_of_223Fr", "type": "standard_name", "name": "surface_radioactivity_content_of_223Fr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Fr\" means the element \"francium\" and \"223Fr\" is the isotope \"francium-223\" with a half-life of 1.53e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_223Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_223Ra.json index 4eb47b575..064e0716f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_223Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_223Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_223Ra", + "id": "surface_radioactivity_content_of_223Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_223Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"223Ra\" is the isotope \"radium-223\" with a half-life of 1.14e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_223Rn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_223Rn.json index e1347cb57..c4ddf885d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_223Rn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_223Rn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_223Rn", + "id": "surface_radioactivity_content_of_223Rn", "type": "standard_name", "name": "surface_radioactivity_content_of_223Rn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rn\" means the element \"radon\" and \"223Rn\" is the isotope \"radon-223\" with a half-life of 2.98e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_224Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_224Ra.json index 5569c1af9..7b646ec6e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_224Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_224Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_224Ra", + "id": "surface_radioactivity_content_of_224Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_224Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"224Ra\" is the isotope \"radium-224\" with a half-life of 3.65e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_225Ac.json b/data_descriptors/standard_name/surface_radioactivity_content_of_225Ac.json index 2c847a6e5..23b9998ab 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_225Ac.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_225Ac.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_225Ac", + "id": "surface_radioactivity_content_of_225Ac", "type": "standard_name", "name": "surface_radioactivity_content_of_225Ac", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ac\" means the element \"actinium\" and \"225Ac\" is the isotope \"actinium-225\" with a half-life of 1.00e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_225Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_225Ra.json index 9ff38f6cb..9665b6a11 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_225Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_225Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_225Ra", + "id": "surface_radioactivity_content_of_225Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_225Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"225Ra\" is the isotope \"radium-225\" with a half-life of 1.48e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_226Ac.json b/data_descriptors/standard_name/surface_radioactivity_content_of_226Ac.json index cfa2d3f46..5ea1dcbd7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_226Ac.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_226Ac.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_226Ac", + "id": "surface_radioactivity_content_of_226Ac", "type": "standard_name", "name": "surface_radioactivity_content_of_226Ac", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ac\" means the element \"actinium\" and \"226Ac\" is the isotope \"actinium-226\" with a half-life of 1.21e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_226Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_226Ra.json index 87e55823a..c58366b36 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_226Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_226Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_226Ra", + "id": "surface_radioactivity_content_of_226Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_226Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"226Ra\" is the isotope \"radium-226\" with a half-life of 5.86e+05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_226Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_226Th.json index 679d13ac3..c5f2349ba 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_226Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_226Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_226Th", + "id": "surface_radioactivity_content_of_226Th", "type": "standard_name", "name": "surface_radioactivity_content_of_226Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"226Th\" is the isotope \"thorium-226\" with a half-life of 2.15e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_227Ac.json b/data_descriptors/standard_name/surface_radioactivity_content_of_227Ac.json index 098f59679..ebb24bde4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_227Ac.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_227Ac.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_227Ac", + "id": "surface_radioactivity_content_of_227Ac", "type": "standard_name", "name": "surface_radioactivity_content_of_227Ac", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ac\" means the element \"actinium\" and \"227Ac\" is the isotope \"actinium-227\" with a half-life of 7.87e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_227Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_227Ra.json index 77b8515e2..ad99de2f0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_227Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_227Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_227Ra", + "id": "surface_radioactivity_content_of_227Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_227Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"227Ra\" is the isotope \"radium-227\" with a half-life of 2.87e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_227Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_227Th.json index cf0ce1985..2bf61606b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_227Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_227Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_227Th", + "id": "surface_radioactivity_content_of_227Th", "type": "standard_name", "name": "surface_radioactivity_content_of_227Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"227Th\" is the isotope \"thorium-227\" with a half-life of 1.82e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_228Ac.json b/data_descriptors/standard_name/surface_radioactivity_content_of_228Ac.json index f6b211f46..a0f6735bc 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_228Ac.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_228Ac.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_228Ac", + "id": "surface_radioactivity_content_of_228Ac", "type": "standard_name", "name": "surface_radioactivity_content_of_228Ac", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ac\" means the element \"actinium\" and \"228Ac\" is the isotope \"actinium-228\" with a half-life of 2.55e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_228Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_228Ra.json index 9a76cf4f6..df72be448 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_228Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_228Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_228Ra", + "id": "surface_radioactivity_content_of_228Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_228Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"228Ra\" is the isotope \"radium-228\" with a half-life of 2.45e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_228Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_228Th.json index 428634d72..6cd0eaa66 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_228Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_228Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_228Th", + "id": "surface_radioactivity_content_of_228Th", "type": "standard_name", "name": "surface_radioactivity_content_of_228Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"228Th\" is the isotope \"thorium-228\" with a half-life of 6.98e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_229Ac.json b/data_descriptors/standard_name/surface_radioactivity_content_of_229Ac.json index add316a06..2b03c10b8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_229Ac.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_229Ac.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_229Ac", + "id": "surface_radioactivity_content_of_229Ac", "type": "standard_name", "name": "surface_radioactivity_content_of_229Ac", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ac\" means the element \"actinium\" and \"229Ac\" is the isotope \"actinium-229\" with a half-life of 4.58e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_229Ra.json b/data_descriptors/standard_name/surface_radioactivity_content_of_229Ra.json index 8a978713c..421862aa3 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_229Ra.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_229Ra.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_229Ra", + "id": "surface_radioactivity_content_of_229Ra", "type": "standard_name", "name": "surface_radioactivity_content_of_229Ra", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ra\" means the element \"radium\" and \"229Ra\" is the isotope \"radium-229\" with a half-life of 1.16e-17 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_229Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_229Th.json index 0bf3252e3..d4a7f60d3 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_229Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_229Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_229Th", + "id": "surface_radioactivity_content_of_229Th", "type": "standard_name", "name": "surface_radioactivity_content_of_229Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"229Th\" is the isotope \"thorium-229\" with a half-life of 2.68e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_230Pa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_230Pa.json index 723dc035e..0f367e2f8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_230Pa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_230Pa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_230Pa", + "id": "surface_radioactivity_content_of_230Pa", "type": "standard_name", "name": "surface_radioactivity_content_of_230Pa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pa\" means the element \"protactinium\" and \"230Pa\" is the isotope \"protactinium-230\" with a half-life of 1.77e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_230Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_230Th.json index a251152de..52680f570 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_230Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_230Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_230Th", + "id": "surface_radioactivity_content_of_230Th", "type": "standard_name", "name": "surface_radioactivity_content_of_230Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"230Th\" is the isotope \"thorium-230\" with a half-life of 2.92e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_230U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_230U.json index c8342ed02..cf010998b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_230U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_230U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_230U", + "id": "surface_radioactivity_content_of_230U", "type": "standard_name", "name": "surface_radioactivity_content_of_230U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"230U\" is the isotope \"uranium-230\" with a half-life of 2.08e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_231Pa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_231Pa.json index 2bde7711c..79a1f2917 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_231Pa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_231Pa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_231Pa", + "id": "surface_radioactivity_content_of_231Pa", "type": "standard_name", "name": "surface_radioactivity_content_of_231Pa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pa\" means the element \"protactinium\" and \"231Pa\" is the isotope \"protactinium-231\" with a half-life of 1.19e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_231Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_231Th.json index d2536e674..831c24b73 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_231Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_231Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_231Th", + "id": "surface_radioactivity_content_of_231Th", "type": "standard_name", "name": "surface_radioactivity_content_of_231Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"231Th\" is the isotope \"thorium-231\" with a half-life of 1.06e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_231U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_231U.json index 1d0705aab..4ffb10e3e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_231U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_231U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_231U", + "id": "surface_radioactivity_content_of_231U", "type": "standard_name", "name": "surface_radioactivity_content_of_231U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"231U\" is the isotope \"uranium-231\" with a half-life of 4.29e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_232Pa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_232Pa.json index c7d5a300c..a5625f624 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_232Pa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_232Pa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_232Pa", + "id": "surface_radioactivity_content_of_232Pa", "type": "standard_name", "name": "surface_radioactivity_content_of_232Pa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pa\" means the element \"protactinium\" and \"232Pa\" is the isotope \"protactinium-232\" with a half-life of 1.31e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_232Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_232Th.json index 9cca8ccf2..96b73251e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_232Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_232Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_232Th", + "id": "surface_radioactivity_content_of_232Th", "type": "standard_name", "name": "surface_radioactivity_content_of_232Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"232Th\" is the isotope \"thorium-232\" with a half-life of 5.14e+12 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_232U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_232U.json index 84923f38e..52fbda8d2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_232U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_232U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_232U", + "id": "surface_radioactivity_content_of_232U", "type": "standard_name", "name": "surface_radioactivity_content_of_232U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"232U\" is the isotope \"uranium-232\" with a half-life of 2.63e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_233Pa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_233Pa.json index 54561e57d..ebe6c1b85 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_233Pa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_233Pa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_233Pa", + "id": "surface_radioactivity_content_of_233Pa", "type": "standard_name", "name": "surface_radioactivity_content_of_233Pa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pa\" means the element \"protactinium\" and \"233Pa\" is the isotope \"protactinium-233\" with a half-life of 2.70e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_233Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_233Th.json index f840d7651..3f9110170 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_233Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_233Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_233Th", + "id": "surface_radioactivity_content_of_233Th", "type": "standard_name", "name": "surface_radioactivity_content_of_233Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"233Th\" is the isotope \"thorium-233\" with a half-life of 1.54e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_233U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_233U.json index aaef00748..613e6bed1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_233U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_233U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_233U", + "id": "surface_radioactivity_content_of_233U", "type": "standard_name", "name": "surface_radioactivity_content_of_233U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"233U\" is the isotope \"uranium-233\" with a half-life of 5.90e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_234Pa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_234Pa.json index e3d7dcf42..7166e32d4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_234Pa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_234Pa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_234Pa", + "id": "surface_radioactivity_content_of_234Pa", "type": "standard_name", "name": "surface_radioactivity_content_of_234Pa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pa\" means the element \"protactinium\" and \"234Pa\" is the isotope \"protactinium-234\" with a half-life of 2.81e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_234Th.json b/data_descriptors/standard_name/surface_radioactivity_content_of_234Th.json index 252900ef9..5e9a405bc 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_234Th.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_234Th.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_234Th", + "id": "surface_radioactivity_content_of_234Th", "type": "standard_name", "name": "surface_radioactivity_content_of_234Th", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Th\" means the element \"thorium\" and \"234Th\" is the isotope \"thorium-234\" with a half-life of 2.41e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_234U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_234U.json index d5b606b3d..16679255c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_234U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_234U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_234U", + "id": "surface_radioactivity_content_of_234U", "type": "standard_name", "name": "surface_radioactivity_content_of_234U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"234U\" is the isotope \"uranium-234\" with a half-life of 9.02e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_234mPa.json b/data_descriptors/standard_name/surface_radioactivity_content_of_234mPa.json index 51e327dc6..febc27816 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_234mPa.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_234mPa.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_234mPa", + "id": "surface_radioactivity_content_of_234mPa", "type": "standard_name", "name": "surface_radioactivity_content_of_234mPa", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pa\" means the element \"protactinium\" and \"234mPa\" is the metastable state of the isotope \"protactinium-234\" with a half-life of 8.13e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_235Np.json b/data_descriptors/standard_name/surface_radioactivity_content_of_235Np.json index 0ac646c39..40abd917d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_235Np.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_235Np.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_235Np", + "id": "surface_radioactivity_content_of_235Np", "type": "standard_name", "name": "surface_radioactivity_content_of_235Np", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"235Np\" is the isotope \"neptunium-235\" with a half-life of 4.09e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_235Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_235Pu.json index ea69a6cee..cbfc34110 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_235Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_235Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_235Pu", + "id": "surface_radioactivity_content_of_235Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_235Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"235Pu\" is the isotope \"plutonium-235\" with a half-life of 1.81e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_235U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_235U.json index b25a32afc..cb4647d41 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_235U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_235U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_235U", + "id": "surface_radioactivity_content_of_235U", "type": "standard_name", "name": "surface_radioactivity_content_of_235U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"235U\" is the isotope \"uranium-235\" with a half-life of 2.60e+11 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_236Np.json b/data_descriptors/standard_name/surface_radioactivity_content_of_236Np.json index 495eb7fa7..82702c9ff 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_236Np.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_236Np.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_236Np", + "id": "surface_radioactivity_content_of_236Np", "type": "standard_name", "name": "surface_radioactivity_content_of_236Np", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"236Np\" is the isotope \"neptunium-236\" with a half-life of 9.17e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_236Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_236Pu.json index a91b44c03..a96512864 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_236Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_236Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_236Pu", + "id": "surface_radioactivity_content_of_236Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_236Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"236Pu\" is the isotope \"plutonium-236\" with a half-life of 1.04e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_236U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_236U.json index 57f50c5ec..46d3f7176 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_236U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_236U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_236U", + "id": "surface_radioactivity_content_of_236U", "type": "standard_name", "name": "surface_radioactivity_content_of_236U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"236U\" is the isotope \"uranium-236\" with a half-life of 8.73e+09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_236mNp.json b/data_descriptors/standard_name/surface_radioactivity_content_of_236mNp.json index 11185094f..4fca0c526 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_236mNp.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_236mNp.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_236mNp", + "id": "surface_radioactivity_content_of_236mNp", "type": "standard_name", "name": "surface_radioactivity_content_of_236mNp", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"236mNp\" is the metastable state of the isotope \"neptunium-236\" with a half-life of 4.72e+10 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_237Np.json b/data_descriptors/standard_name/surface_radioactivity_content_of_237Np.json index 7f40ce47e..66838a089 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_237Np.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_237Np.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_237Np", + "id": "surface_radioactivity_content_of_237Np", "type": "standard_name", "name": "surface_radioactivity_content_of_237Np", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"237Np\" is the isotope \"neptunium-237\" with a half-life of 7.79e+08 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_237Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_237Pu.json index 31d0ad8dc..7b8c69d31 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_237Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_237Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_237Pu", + "id": "surface_radioactivity_content_of_237Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_237Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"237Pu\" is the isotope \"plutonium-237\" with a half-life of 4.56e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_237U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_237U.json index 5c80589f8..476840f80 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_237U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_237U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_237U", + "id": "surface_radioactivity_content_of_237U", "type": "standard_name", "name": "surface_radioactivity_content_of_237U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"237U\" is the isotope \"uranium-237\" with a half-life of 6.74e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_238Np.json b/data_descriptors/standard_name/surface_radioactivity_content_of_238Np.json index 7321b7d4b..77ecbd6db 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_238Np.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_238Np.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_238Np", + "id": "surface_radioactivity_content_of_238Np", "type": "standard_name", "name": "surface_radioactivity_content_of_238Np", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"238Np\" is the isotope \"neptunium-238\" with a half-life of 2.10e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_238Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_238Pu.json index cf3340056..bf90ef4d4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_238Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_238Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_238Pu", + "id": "surface_radioactivity_content_of_238Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_238Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"238Pu\" is the isotope \"plutonium-238\" with a half-life of 3.15e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_238U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_238U.json index d6e71eb78..7a8e84fc7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_238U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_238U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_238U", + "id": "surface_radioactivity_content_of_238U", "type": "standard_name", "name": "surface_radioactivity_content_of_238U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"238U\" is the isotope \"uranium-238\" with a half-life of 1.65e+12 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_239Np.json b/data_descriptors/standard_name/surface_radioactivity_content_of_239Np.json index 5955e0f21..31a051299 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_239Np.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_239Np.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_239Np", + "id": "surface_radioactivity_content_of_239Np", "type": "standard_name", "name": "surface_radioactivity_content_of_239Np", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"239Np\" is the isotope \"neptunium-239\" with a half-life of 2.35e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_239Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_239Pu.json index ab2002cb9..43808ece2 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_239Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_239Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_239Pu", + "id": "surface_radioactivity_content_of_239Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_239Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"239Pu\" is the isotope \"plutonium-239\" with a half-life of 8.91e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_239U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_239U.json index a42f04467..3812cb63c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_239U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_239U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_239U", + "id": "surface_radioactivity_content_of_239U", "type": "standard_name", "name": "surface_radioactivity_content_of_239U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"239U\" is the isotope \"uranium-239\" with a half-life of 1.63e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_240Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_240Am.json index 1f5abfbb8..b5bce9d20 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_240Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_240Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_240Am", + "id": "surface_radioactivity_content_of_240Am", "type": "standard_name", "name": "surface_radioactivity_content_of_240Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"240Am\" is the isotope \"americium-240\" with a half-life of 2.12e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_240Np.json b/data_descriptors/standard_name/surface_radioactivity_content_of_240Np.json index 01de8b903..2ed9c0965 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_240Np.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_240Np.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_240Np", + "id": "surface_radioactivity_content_of_240Np", "type": "standard_name", "name": "surface_radioactivity_content_of_240Np", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"240Np\" is the isotope \"neptunium-240\" with a half-life of 4.38e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_240Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_240Pu.json index f095a1964..3ee8faa74 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_240Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_240Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_240Pu", + "id": "surface_radioactivity_content_of_240Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_240Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"240Pu\" is the isotope \"plutonium-240\" with a half-life of 2.40e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_240U.json b/data_descriptors/standard_name/surface_radioactivity_content_of_240U.json index 36f5421dc..fc961b643 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_240U.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_240U.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_240U", + "id": "surface_radioactivity_content_of_240U", "type": "standard_name", "name": "surface_radioactivity_content_of_240U", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"U\" means the element \"uranium\" and \"240U\" is the isotope \"uranium-240\" with a half-life of 5.99e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_240mNp.json b/data_descriptors/standard_name/surface_radioactivity_content_of_240mNp.json index 06a15e4d9..8334ab0f1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_240mNp.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_240mNp.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_240mNp", + "id": "surface_radioactivity_content_of_240mNp", "type": "standard_name", "name": "surface_radioactivity_content_of_240mNp", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Np\" means the element \"neptunium\" and \"240mNp\" is the metastable state of the isotope \"neptunium-240\" with a half-life of 5.08e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_241Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_241Am.json index 907c05d8a..f491a9232 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_241Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_241Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_241Am", + "id": "surface_radioactivity_content_of_241Am", "type": "standard_name", "name": "surface_radioactivity_content_of_241Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"241Am\" is the isotope \"americium-241\" with a half-life of 1.67e+05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_241Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_241Cm.json index 0214981d7..b81068616 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_241Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_241Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_241Cm", + "id": "surface_radioactivity_content_of_241Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_241Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"241Cm\" is the isotope \"curium-241\" with a half-life of 3.50e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_241Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_241Pu.json index 2a7ccade8..b5707f5e1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_241Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_241Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_241Pu", + "id": "surface_radioactivity_content_of_241Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_241Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"241Pu\" is the isotope \"plutonium-241\" with a half-life of 4.83e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_242Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_242Am.json index 11e924714..ecbbacd9a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_242Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_242Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_242Am", + "id": "surface_radioactivity_content_of_242Am", "type": "standard_name", "name": "surface_radioactivity_content_of_242Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"242Am\" is the isotope \"americium-242\" with a half-life of 6.69e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_242Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_242Cm.json index 02b3104b8..f471a3817 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_242Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_242Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_242Cm", + "id": "surface_radioactivity_content_of_242Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_242Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"242Cm\" is the isotope \"curium-242\" with a half-life of 1.63e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_242Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_242Pu.json index 9cf947b85..71b7444f7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_242Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_242Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_242Pu", + "id": "surface_radioactivity_content_of_242Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_242Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"242Pu\" is the isotope \"plutonium-242\" with a half-life of 1.38e+08 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_242m1Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_242m1Am.json index c2b1b3163..8fc3f5ca9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_242m1Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_242m1Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_242m1Am", + "id": "surface_radioactivity_content_of_242m1Am", "type": "standard_name", "name": "surface_radioactivity_content_of_242m1Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"242m1Am\" is the metastable state of the isotope \"americium-242\" with a half-life of 5.53e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_242m2Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_242m2Am.json index b35b23399..c6e6ed1f6 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_242m2Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_242m2Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_242m2Am", + "id": "surface_radioactivity_content_of_242m2Am", "type": "standard_name", "name": "surface_radioactivity_content_of_242m2Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"242m2Am\" is the metastable state of the isotope \"americium-242\" with a half-life of 1.62e-07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_243Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_243Am.json index 87d98f828..0732db8d5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_243Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_243Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_243Am", + "id": "surface_radioactivity_content_of_243Am", "type": "standard_name", "name": "surface_radioactivity_content_of_243Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"243Am\" is the isotope \"americium-243\" with a half-life of 2.91e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_243Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_243Cm.json index b3be5ae9b..a4033f205 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_243Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_243Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_243Cm", + "id": "surface_radioactivity_content_of_243Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_243Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"243Cm\" is the isotope \"curium-243\" with a half-life of 1.17e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_243Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_243Pu.json index 93737f3c6..e49c4401e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_243Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_243Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_243Pu", + "id": "surface_radioactivity_content_of_243Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_243Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"243Pu\" is the isotope \"plutonium-243\" with a half-life of 2.07e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_244Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_244Am.json index 38b1a5989..215256b2f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_244Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_244Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_244Am", + "id": "surface_radioactivity_content_of_244Am", "type": "standard_name", "name": "surface_radioactivity_content_of_244Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"244Am\" is the isotope \"americium-244\" with a half-life of 4.20e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_244Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_244Cm.json index 965215c9f..afe1f4c47 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_244Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_244Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_244Cm", + "id": "surface_radioactivity_content_of_244Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_244Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"244Cm\" is the isotope \"curium-244\" with a half-life of 6.42e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_244Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_244Pu.json index 71ad837af..91618b03e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_244Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_244Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_244Pu", + "id": "surface_radioactivity_content_of_244Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_244Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"244Pu\" is the isotope \"plutonium-244\" with a half-life of 2.92e+10 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_244mAm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_244mAm.json index 16746481f..539f6f51e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_244mAm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_244mAm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_244mAm", + "id": "surface_radioactivity_content_of_244mAm", "type": "standard_name", "name": "surface_radioactivity_content_of_244mAm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"244mAm\" is the metastable state of the isotope \"americium-244\" with a half-life of 1.81e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_245Am.json b/data_descriptors/standard_name/surface_radioactivity_content_of_245Am.json index 611ee19e7..7883685bb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_245Am.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_245Am.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_245Am", + "id": "surface_radioactivity_content_of_245Am", "type": "standard_name", "name": "surface_radioactivity_content_of_245Am", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Am\" means the element \"americium\" and \"245Am\" is the isotope \"americium-245\" with a half-life of 8.75e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_245Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_245Cm.json index 12014ad48..c17f711c5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_245Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_245Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_245Cm", + "id": "surface_radioactivity_content_of_245Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_245Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"245Cm\" is the isotope \"curium-245\" with a half-life of 3.40e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_245Pu.json b/data_descriptors/standard_name/surface_radioactivity_content_of_245Pu.json index 239b63e38..b7a605cc7 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_245Pu.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_245Pu.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_245Pu", + "id": "surface_radioactivity_content_of_245Pu", "type": "standard_name", "name": "surface_radioactivity_content_of_245Pu", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Pu\" means the element \"plutonium\" and \"245Pu\" is the isotope \"plutonium-245\" with a half-life of 4.16e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_246Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_246Cm.json index 547aec3d6..c835701fe 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_246Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_246Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_246Cm", + "id": "surface_radioactivity_content_of_246Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_246Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"246Cm\" is the isotope \"curium-246\" with a half-life of 2.01e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_247Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_247Cm.json index 66c3fbb5d..b1cfe58c4 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_247Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_247Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_247Cm", + "id": "surface_radioactivity_content_of_247Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_247Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"247Cm\" is the isotope \"curium-247\" with a half-life of 5.86e+09 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_248Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_248Cm.json index 9b54c4704..3ac4a6715 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_248Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_248Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_248Cm", + "id": "surface_radioactivity_content_of_248Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_248Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"248Cm\" is the isotope \"curium-248\" with a half-life of 1.72e+08 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_249Bk.json b/data_descriptors/standard_name/surface_radioactivity_content_of_249Bk.json index 83017fcf5..1fbc0b188 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_249Bk.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_249Bk.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_249Bk", + "id": "surface_radioactivity_content_of_249Bk", "type": "standard_name", "name": "surface_radioactivity_content_of_249Bk", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bk\" means the element \"berkelium\" and \"249Bk\" is the isotope \"berkelium-249\" with a half-life of 3.15e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_249Cf.json b/data_descriptors/standard_name/surface_radioactivity_content_of_249Cf.json index 031022a69..be83271f1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_249Cf.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_249Cf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_249Cf", + "id": "surface_radioactivity_content_of_249Cf", "type": "standard_name", "name": "surface_radioactivity_content_of_249Cf", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cf\" means the element \"californium\" and \"249Cf\" is the isotope \"californium-249\" with a half-life of 1.32e+05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_249Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_249Cm.json index c5c2a9a1d..27fbefacd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_249Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_249Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_249Cm", + "id": "surface_radioactivity_content_of_249Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_249Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"249Cm\" is the isotope \"curium-249\" with a half-life of 4.43e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_24Na.json b/data_descriptors/standard_name/surface_radioactivity_content_of_24Na.json index 97aa83769..ce7541198 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_24Na.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_24Na.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_24Na", + "id": "surface_radioactivity_content_of_24Na", "type": "standard_name", "name": "surface_radioactivity_content_of_24Na", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Na\" means the element \"sodium\" and \"24Na\" is the isotope \"sodium-24\" with a half-life of 6.27e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_250Bk.json b/data_descriptors/standard_name/surface_radioactivity_content_of_250Bk.json index 88414fc27..987a4ec87 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_250Bk.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_250Bk.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_250Bk", + "id": "surface_radioactivity_content_of_250Bk", "type": "standard_name", "name": "surface_radioactivity_content_of_250Bk", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Bk\" means the element \"berkelium\" and \"250Bk\" is the isotope \"berkelium-250\" with a half-life of 1.34e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_250Cf.json b/data_descriptors/standard_name/surface_radioactivity_content_of_250Cf.json index d7c8b7eb6..01bc100fd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_250Cf.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_250Cf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_250Cf", + "id": "surface_radioactivity_content_of_250Cf", "type": "standard_name", "name": "surface_radioactivity_content_of_250Cf", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cf\" means the element \"californium\" and \"250Cf\" is the isotope \"californium-250\" with a half-life of 4.75e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_250Cm.json b/data_descriptors/standard_name/surface_radioactivity_content_of_250Cm.json index 6ef2e9329..809b373bb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_250Cm.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_250Cm.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_250Cm", + "id": "surface_radioactivity_content_of_250Cm", "type": "standard_name", "name": "surface_radioactivity_content_of_250Cm", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cm\" means the element \"curium\" and \"250Cm\" is the isotope \"curium-250\" with a half-life of 2.52e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_251Cf.json b/data_descriptors/standard_name/surface_radioactivity_content_of_251Cf.json index f2b5d14fa..80a114537 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_251Cf.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_251Cf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_251Cf", + "id": "surface_radioactivity_content_of_251Cf", "type": "standard_name", "name": "surface_radioactivity_content_of_251Cf", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cf\" means the element \"californium\" and \"251Cf\" is the isotope \"californium-251\" with a half-life of 2.92e+05 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_252Cf.json b/data_descriptors/standard_name/surface_radioactivity_content_of_252Cf.json index b53e0fbc9..b84788d1c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_252Cf.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_252Cf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_252Cf", + "id": "surface_radioactivity_content_of_252Cf", "type": "standard_name", "name": "surface_radioactivity_content_of_252Cf", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cf\" means the element \"californium\" and \"252Cf\" is the isotope \"californium-252\" with a half-life of 9.68e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_253Cf.json b/data_descriptors/standard_name/surface_radioactivity_content_of_253Cf.json index d9e71732f..15f77a377 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_253Cf.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_253Cf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_253Cf", + "id": "surface_radioactivity_content_of_253Cf", "type": "standard_name", "name": "surface_radioactivity_content_of_253Cf", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cf\" means the element \"californium\" and \"253Cf\" is the isotope \"californium-253\" with a half-life of 1.76e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_253Es.json b/data_descriptors/standard_name/surface_radioactivity_content_of_253Es.json index a2b19a54d..53d4ce8a5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_253Es.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_253Es.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_253Es", + "id": "surface_radioactivity_content_of_253Es", "type": "standard_name", "name": "surface_radioactivity_content_of_253Es", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Es\" means the element \"einsteinium\" and \"253Es\" is the isotope \"einsteinium-253\" with a half-life of 2.05e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_254Cf.json b/data_descriptors/standard_name/surface_radioactivity_content_of_254Cf.json index 21b43e8eb..17c70b900 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_254Cf.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_254Cf.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_254Cf", + "id": "surface_radioactivity_content_of_254Cf", "type": "standard_name", "name": "surface_radioactivity_content_of_254Cf", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Cf\" means the element \"californium\" and \"254Cf\" is the isotope \"californium-254\" with a half-life of 6.03e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_254Es.json b/data_descriptors/standard_name/surface_radioactivity_content_of_254Es.json index 716a90b9a..b5e5beed1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_254Es.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_254Es.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_254Es", + "id": "surface_radioactivity_content_of_254Es", "type": "standard_name", "name": "surface_radioactivity_content_of_254Es", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Es\" means the element \"einsteinium\" and \"254Es\" is the isotope \"einsteinium-254\" with a half-life of 2.76e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_254mEs.json b/data_descriptors/standard_name/surface_radioactivity_content_of_254mEs.json index 632bc9d11..df183abd3 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_254mEs.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_254mEs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_254mEs", + "id": "surface_radioactivity_content_of_254mEs", "type": "standard_name", "name": "surface_radioactivity_content_of_254mEs", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Es\" means the element \"einsteinium\" and \"254mEs\" is the metastable state of the isotope \"einsteinium-254\" with a half-life of 1.63e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_255Es.json b/data_descriptors/standard_name/surface_radioactivity_content_of_255Es.json index 0a0548610..c6c5ad6cf 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_255Es.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_255Es.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_255Es", + "id": "surface_radioactivity_content_of_255Es", "type": "standard_name", "name": "surface_radioactivity_content_of_255Es", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Es\" means the element \"einsteinium\" and \"255Es\" is the isotope \"einsteinium-255\" with a half-life of 3.84e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_3H.json b/data_descriptors/standard_name/surface_radioactivity_content_of_3H.json index 3d0b7b2ac..ebcac3659 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_3H.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_3H.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_3H", + "id": "surface_radioactivity_content_of_3H", "type": "standard_name", "name": "surface_radioactivity_content_of_3H", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"H\" means the element \"hydrogen\" and \"3H\" is the isotope \"hydrogen-3\" with a half-life of 4.51e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_41Ar.json b/data_descriptors/standard_name/surface_radioactivity_content_of_41Ar.json index 37cde8fc0..070a57b7b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_41Ar.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_41Ar.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_41Ar", + "id": "surface_radioactivity_content_of_41Ar", "type": "standard_name", "name": "surface_radioactivity_content_of_41Ar", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ar\" means the element \"argon\" and \"41Ar\" is the isotope \"argon-41\" with a half-life of 7.64e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_54Mn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_54Mn.json index b8473f8fa..b1d4f7747 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_54Mn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_54Mn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_54Mn", + "id": "surface_radioactivity_content_of_54Mn", "type": "standard_name", "name": "surface_radioactivity_content_of_54Mn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Mn\" means the element \"manganese\" and \"54Mn\" is the isotope \"manganese-54\" with a half-life of 3.12e+02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_58Co.json b/data_descriptors/standard_name/surface_radioactivity_content_of_58Co.json index ef87964ed..e2e7e7d42 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_58Co.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_58Co.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_58Co", + "id": "surface_radioactivity_content_of_58Co", "type": "standard_name", "name": "surface_radioactivity_content_of_58Co", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Co\" means the element \"cobalt\" and \"58Co\" is the isotope \"cobalt-58\" with a half-life of 7.10e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_60Co.json b/data_descriptors/standard_name/surface_radioactivity_content_of_60Co.json index 9db4f572b..26a3ab9a9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_60Co.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_60Co.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_60Co", + "id": "surface_radioactivity_content_of_60Co", "type": "standard_name", "name": "surface_radioactivity_content_of_60Co", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Co\" means the element \"cobalt\" and \"60Co\" is the isotope \"cobalt-60\" with a half-life of 1.93e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_72Ga.json b/data_descriptors/standard_name/surface_radioactivity_content_of_72Ga.json index 280516b5e..a4b865b20 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_72Ga.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_72Ga.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_72Ga", + "id": "surface_radioactivity_content_of_72Ga", "type": "standard_name", "name": "surface_radioactivity_content_of_72Ga", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ga\" means the element \"gallium\" and \"72Ga\" is the isotope \"gallium-72\" with a half-life of 5.86e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_72Zn.json b/data_descriptors/standard_name/surface_radioactivity_content_of_72Zn.json index 804acef1e..f036bc543 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_72Zn.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_72Zn.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_72Zn", + "id": "surface_radioactivity_content_of_72Zn", "type": "standard_name", "name": "surface_radioactivity_content_of_72Zn", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Zn\" means the element \"zinc\" and \"72Zn\" is the isotope \"zinc-72\" with a half-life of 1.94e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_73Ga.json b/data_descriptors/standard_name/surface_radioactivity_content_of_73Ga.json index efcfd67b1..609fb6995 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_73Ga.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_73Ga.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_73Ga", + "id": "surface_radioactivity_content_of_73Ga", "type": "standard_name", "name": "surface_radioactivity_content_of_73Ga", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ga\" means the element \"gallium\" and \"73Ga\" is the isotope \"gallium-73\" with a half-life of 2.03e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_75Ge.json b/data_descriptors/standard_name/surface_radioactivity_content_of_75Ge.json index 64d708880..c8e74f6ca 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_75Ge.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_75Ge.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_75Ge", + "id": "surface_radioactivity_content_of_75Ge", "type": "standard_name", "name": "surface_radioactivity_content_of_75Ge", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ge\" means the element \"germanium\" and \"75Ge\" is the isotope \"germanium-75\" with a half-life of 5.73e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_77As.json b/data_descriptors/standard_name/surface_radioactivity_content_of_77As.json index fdad4f730..b36cba81e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_77As.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_77As.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_77As", + "id": "surface_radioactivity_content_of_77As", "type": "standard_name", "name": "surface_radioactivity_content_of_77As", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"As\" means the element \"arsenic\" and \"77As\" is the isotope \"arsenic-77\" with a half-life of 1.62e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_77Ge.json b/data_descriptors/standard_name/surface_radioactivity_content_of_77Ge.json index 7fef057f2..d2668ee29 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_77Ge.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_77Ge.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_77Ge", + "id": "surface_radioactivity_content_of_77Ge", "type": "standard_name", "name": "surface_radioactivity_content_of_77Ge", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ge\" means the element \"germanium\" and \"77Ge\" is the isotope \"germanium-77\" with a half-life of 4.72e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_77mGe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_77mGe.json index 020e7b2fa..9345bbb6d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_77mGe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_77mGe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_77mGe", + "id": "surface_radioactivity_content_of_77mGe", "type": "standard_name", "name": "surface_radioactivity_content_of_77mGe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ge\" means the element \"germanium\" and \"77mGe\" is the metastable state of the isotope \"germanium-77\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_78As.json b/data_descriptors/standard_name/surface_radioactivity_content_of_78As.json index d6eebf81e..8e0ccad9e 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_78As.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_78As.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_78As", + "id": "surface_radioactivity_content_of_78As", "type": "standard_name", "name": "surface_radioactivity_content_of_78As", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"As\" means the element \"arsenic\" and \"78As\" is the isotope \"arsenic-78\" with a half-life of 6.32e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_78Ge.json b/data_descriptors/standard_name/surface_radioactivity_content_of_78Ge.json index 27a34aaaa..6a64dbd22 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_78Ge.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_78Ge.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_78Ge", + "id": "surface_radioactivity_content_of_78Ge", "type": "standard_name", "name": "surface_radioactivity_content_of_78Ge", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Ge\" means the element \"germanium\" and \"78Ge\" is the isotope \"germanium-78\" with a half-life of 6.03e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_79Se.json b/data_descriptors/standard_name/surface_radioactivity_content_of_79Se.json index 6f72ec011..87da5ed66 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_79Se.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_79Se.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_79Se", + "id": "surface_radioactivity_content_of_79Se", "type": "standard_name", "name": "surface_radioactivity_content_of_79Se", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Se\" means the element \"selenium\" and \"79Se\" is the isotope \"selenium-79\" with a half-life of 2.37e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_81Se.json b/data_descriptors/standard_name/surface_radioactivity_content_of_81Se.json index aaf8acf65..52ea97aa0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_81Se.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_81Se.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_81Se", + "id": "surface_radioactivity_content_of_81Se", "type": "standard_name", "name": "surface_radioactivity_content_of_81Se", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Se\" means the element \"selenium\" and \"81Se\" is the isotope \"selenium-81\" with a half-life of 1.28e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_81mSe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_81mSe.json index a05a8d420..a95359dfd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_81mSe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_81mSe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_81mSe", + "id": "surface_radioactivity_content_of_81mSe", "type": "standard_name", "name": "surface_radioactivity_content_of_81mSe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Se\" means the element \"selenium\" and \"81mSe\" is the metastable state of the isotope \"selenium-81\" with a half-life of 3.97e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_82Br.json b/data_descriptors/standard_name/surface_radioactivity_content_of_82Br.json index b26bb91af..28cc9e633 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_82Br.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_82Br.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_82Br", + "id": "surface_radioactivity_content_of_82Br", "type": "standard_name", "name": "surface_radioactivity_content_of_82Br", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Br\" means the element \"bromine\" and \"82Br\" is the isotope \"bromine-82\" with a half-life of 1.47e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_82mBr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_82mBr.json index 52d2424c5..41c360285 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_82mBr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_82mBr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_82mBr", + "id": "surface_radioactivity_content_of_82mBr", "type": "standard_name", "name": "surface_radioactivity_content_of_82mBr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Br\" means the element \"bromine\" and \"82mBr\" is the metastable state of the isotope \"bromine-82\" with a half-life of 4.24e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_83Br.json b/data_descriptors/standard_name/surface_radioactivity_content_of_83Br.json index 418d811ba..7727a3025 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_83Br.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_83Br.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_83Br", + "id": "surface_radioactivity_content_of_83Br", "type": "standard_name", "name": "surface_radioactivity_content_of_83Br", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Br\" means the element \"bromine\" and \"83Br\" is the isotope \"bromine-83\" with a half-life of 1.00e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_83Se.json b/data_descriptors/standard_name/surface_radioactivity_content_of_83Se.json index ee7098a55..38b325882 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_83Se.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_83Se.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_83Se", + "id": "surface_radioactivity_content_of_83Se", "type": "standard_name", "name": "surface_radioactivity_content_of_83Se", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Se\" means the element \"selenium\" and \"83Se\" is the isotope \"selenium-83\" with a half-life of 1.56e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_83mKr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_83mKr.json index d6edc4bf3..3b9da390a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_83mKr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_83mKr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_83mKr", + "id": "surface_radioactivity_content_of_83mKr", "type": "standard_name", "name": "surface_radioactivity_content_of_83mKr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Kr\" means the element \"krypton\" and \"83mKr\" is the metastable state of the isotope \"krypton-83\" with a half-life of 7.71e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_83mSe.json b/data_descriptors/standard_name/surface_radioactivity_content_of_83mSe.json index d44c9d517..eeadba3df 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_83mSe.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_83mSe.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_83mSe", + "id": "surface_radioactivity_content_of_83mSe", "type": "standard_name", "name": "surface_radioactivity_content_of_83mSe", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Se\" means the element \"selenium\" and \"83mSe\" is the metastable state of the isotope \"selenium-83\" with a half-life of 8.10e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_84Br.json b/data_descriptors/standard_name/surface_radioactivity_content_of_84Br.json index 50852da11..6fe670950 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_84Br.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_84Br.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_84Br", + "id": "surface_radioactivity_content_of_84Br", "type": "standard_name", "name": "surface_radioactivity_content_of_84Br", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Br\" means the element \"bromine\" and \"84Br\" is the isotope \"bromine-84\" with a half-life of 2.21e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_84mBr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_84mBr.json index 532596b8d..10ee7fecb 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_84mBr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_84mBr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_84mBr", + "id": "surface_radioactivity_content_of_84mBr", "type": "standard_name", "name": "surface_radioactivity_content_of_84mBr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Br\" means the element \"bromine\" and \"84mBr\" is the metastable state of the isotope \"bromine-84\" with a half-life of 4.16e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_85Kr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_85Kr.json index 469f07aa6..653df6cd9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_85Kr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_85Kr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_85Kr", + "id": "surface_radioactivity_content_of_85Kr", "type": "standard_name", "name": "surface_radioactivity_content_of_85Kr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Kr\" means the element \"krypton\" and \"85Kr\" is the isotope \"krypton-85\" with a half-life of 3.95e+03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_85mKr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_85mKr.json index d7d478703..c0246fc6c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_85mKr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_85mKr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_85mKr", + "id": "surface_radioactivity_content_of_85mKr", "type": "standard_name", "name": "surface_radioactivity_content_of_85mKr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Kr\" means the element \"krypton\" and \"85mKr\" is the metastable state of the isotope \"krypton-85\" with a half-life of 1.83e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_86Rb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_86Rb.json index cef4423fc..866e20bb0 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_86Rb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_86Rb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_86Rb", + "id": "surface_radioactivity_content_of_86Rb", "type": "standard_name", "name": "surface_radioactivity_content_of_86Rb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rb\" means the element \"rubidium\" and \"86Rb\" is the isotope \"rubidium-86\" with a half-life of 1.87e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_86mRb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_86mRb.json index f059ee6d6..1bec98b61 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_86mRb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_86mRb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_86mRb", + "id": "surface_radioactivity_content_of_86mRb", "type": "standard_name", "name": "surface_radioactivity_content_of_86mRb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rb\" means the element \"rubidium\" and \"86mRb\" is the metastable state of the isotope \"rubidium-86\" with a half-life of 7.04e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_87Kr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_87Kr.json index 6d4729f21..f02057cb1 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_87Kr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_87Kr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_87Kr", + "id": "surface_radioactivity_content_of_87Kr", "type": "standard_name", "name": "surface_radioactivity_content_of_87Kr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Kr\" means the element \"krypton\" and \"87Kr\" is the isotope \"krypton-87\" with a half-life of 5.28e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_87Rb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_87Rb.json index 29a77283b..531b7b53a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_87Rb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_87Rb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_87Rb", + "id": "surface_radioactivity_content_of_87Rb", "type": "standard_name", "name": "surface_radioactivity_content_of_87Rb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rb\" means the element \"rubidium\" and \"87Rb\" is the isotope \"rubidium-87\" with a half-life of 1.71e+13 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_88Kr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_88Kr.json index 8be6a568f..25b1231ba 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_88Kr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_88Kr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_88Kr", + "id": "surface_radioactivity_content_of_88Kr", "type": "standard_name", "name": "surface_radioactivity_content_of_88Kr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Kr\" means the element \"krypton\" and \"88Kr\" is the isotope \"krypton-88\" with a half-life of 1.17e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_88Rb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_88Rb.json index 601ef8e11..98f01c858 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_88Rb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_88Rb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_88Rb", + "id": "surface_radioactivity_content_of_88Rb", "type": "standard_name", "name": "surface_radioactivity_content_of_88Rb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rb\" means the element \"rubidium\" and \"88Rb\" is the isotope \"rubidium-88\" with a half-life of 1.25e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_89Kr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_89Kr.json index 627f40b39..e142c47fd 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_89Kr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_89Kr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_89Kr", + "id": "surface_radioactivity_content_of_89Kr", "type": "standard_name", "name": "surface_radioactivity_content_of_89Kr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Kr\" means the element \"krypton\" and \"89Kr\" is the isotope \"krypton-89\" with a half-life of 2.20e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_89Rb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_89Rb.json index 62f271e1d..ec9019e0c 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_89Rb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_89Rb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_89Rb", + "id": "surface_radioactivity_content_of_89Rb", "type": "standard_name", "name": "surface_radioactivity_content_of_89Rb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Rb\" means the element \"rubidium\" and \"89Rb\" is the isotope \"rubidium-89\" with a half-life of 1.06e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_89Sr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_89Sr.json index c8e57ac48..78b82e000 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_89Sr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_89Sr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_89Sr", + "id": "surface_radioactivity_content_of_89Sr", "type": "standard_name", "name": "surface_radioactivity_content_of_89Sr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sr\" means the element \"strontium\" and \"89Sr\" is the isotope \"strontium-89\" with a half-life of 5.21e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_90Sr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_90Sr.json index 88ebbe9ee..37343d661 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_90Sr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_90Sr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_90Sr", + "id": "surface_radioactivity_content_of_90Sr", "type": "standard_name", "name": "surface_radioactivity_content_of_90Sr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sr\" means the element \"strontium\" and \"90Sr\" is the isotope \"strontium-90\" with a half-life of 1.02e+04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_90Y.json b/data_descriptors/standard_name/surface_radioactivity_content_of_90Y.json index 327557620..e7ed5a2a9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_90Y.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_90Y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_90Y", + "id": "surface_radioactivity_content_of_90Y", "type": "standard_name", "name": "surface_radioactivity_content_of_90Y", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"90Y\" is the isotope \"yttrium-90\" with a half-life of 2.67e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_90mY.json b/data_descriptors/standard_name/surface_radioactivity_content_of_90mY.json index 85f20cc39..f696f08b8 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_90mY.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_90mY.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_90mY", + "id": "surface_radioactivity_content_of_90mY", "type": "standard_name", "name": "surface_radioactivity_content_of_90mY", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"90mY\" is the metastable state of the isotope \"yttrium-90\" with a half-life of 1.33e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_91Sr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_91Sr.json index e0ef554bf..9dce8dd27 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_91Sr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_91Sr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_91Sr", + "id": "surface_radioactivity_content_of_91Sr", "type": "standard_name", "name": "surface_radioactivity_content_of_91Sr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sr\" means the element \"strontium\" and \"91Sr\" is the isotope \"strontium-91\" with a half-life of 3.95e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_91Y.json b/data_descriptors/standard_name/surface_radioactivity_content_of_91Y.json index 64f74afb6..90beb0bb9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_91Y.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_91Y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_91Y", + "id": "surface_radioactivity_content_of_91Y", "type": "standard_name", "name": "surface_radioactivity_content_of_91Y", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"91Y\" is the isotope \"yttrium-91\" with a half-life of 5.86e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_91mY.json b/data_descriptors/standard_name/surface_radioactivity_content_of_91mY.json index b42fb27d1..7452b7db5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_91mY.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_91mY.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_91mY", + "id": "surface_radioactivity_content_of_91mY", "type": "standard_name", "name": "surface_radioactivity_content_of_91mY", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"91mY\" is the metastable state of the isotope \"yttrium-91\" with a half-life of 3.46e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_92Sr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_92Sr.json index a3993f2f2..d9f3a3069 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_92Sr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_92Sr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_92Sr", + "id": "surface_radioactivity_content_of_92Sr", "type": "standard_name", "name": "surface_radioactivity_content_of_92Sr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Sr\" means the element \"strontium\" and \"92Sr\" is the isotope \"strontium-92\" with a half-life of 1.13e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_92Y.json b/data_descriptors/standard_name/surface_radioactivity_content_of_92Y.json index 29663262e..78bbdc9ab 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_92Y.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_92Y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_92Y", + "id": "surface_radioactivity_content_of_92Y", "type": "standard_name", "name": "surface_radioactivity_content_of_92Y", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"92Y\" is the isotope \"yttrium-92\" with a half-life of 1.47e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_93Y.json b/data_descriptors/standard_name/surface_radioactivity_content_of_93Y.json index c04003ac7..a70457456 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_93Y.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_93Y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_93Y", + "id": "surface_radioactivity_content_of_93Y", "type": "standard_name", "name": "surface_radioactivity_content_of_93Y", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"93Y\" is the isotope \"yttrium-93\" with a half-life of 4.24e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_93Zr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_93Zr.json index 147de690d..3ce2b2843 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_93Zr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_93Zr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_93Zr", + "id": "surface_radioactivity_content_of_93Zr", "type": "standard_name", "name": "surface_radioactivity_content_of_93Zr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Zr\" means the element \"zirconium\" and \"93Zr\" is the isotope \"zirconium-93\" with a half-life of 3.47e+08 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_94Nb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_94Nb.json index 9d218ce49..a8e4ced1f 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_94Nb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_94Nb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_94Nb", + "id": "surface_radioactivity_content_of_94Nb", "type": "standard_name", "name": "surface_radioactivity_content_of_94Nb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"94Nb\" is the isotope \"niobium-94\" with a half-life of 7.29e+06 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_94Y.json b/data_descriptors/standard_name/surface_radioactivity_content_of_94Y.json index 3b5f0aa10..fb3990dd9 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_94Y.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_94Y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_94Y", + "id": "surface_radioactivity_content_of_94Y", "type": "standard_name", "name": "surface_radioactivity_content_of_94Y", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"94Y\" is the isotope \"yttrium-94\" with a half-life of 1.32e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_94mNb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_94mNb.json index 4e9e30abc..e99f9234a 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_94mNb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_94mNb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_94mNb", + "id": "surface_radioactivity_content_of_94mNb", "type": "standard_name", "name": "surface_radioactivity_content_of_94mNb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"94mNb\" is the metastable state of the isotope \"niobium-94\" with a half-life of 4.34e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_95Nb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_95Nb.json index f9f96b2c4..1f6bd25ac 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_95Nb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_95Nb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_95Nb", + "id": "surface_radioactivity_content_of_95Nb", "type": "standard_name", "name": "surface_radioactivity_content_of_95Nb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"95Nb\" is the isotope \"niobium-95\" with a half-life of 3.52e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_95Y.json b/data_descriptors/standard_name/surface_radioactivity_content_of_95Y.json index ff0d8785b..ed8410930 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_95Y.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_95Y.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_95Y", + "id": "surface_radioactivity_content_of_95Y", "type": "standard_name", "name": "surface_radioactivity_content_of_95Y", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Y\" means the element \"yttrium\" and \"95Y\" is the isotope \"yttrium-95\" with a half-life of 7.29e-03 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_95Zr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_95Zr.json index ed0f226f1..57ea5885d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_95Zr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_95Zr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_95Zr", + "id": "surface_radioactivity_content_of_95Zr", "type": "standard_name", "name": "surface_radioactivity_content_of_95Zr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Zr\" means the element \"zirconium\" and \"95Zr\" is the isotope \"zirconium-95\" with a half-life of 6.52e+01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_95mNb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_95mNb.json index d46cdf212..fcfa57eae 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_95mNb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_95mNb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_95mNb", + "id": "surface_radioactivity_content_of_95mNb", "type": "standard_name", "name": "surface_radioactivity_content_of_95mNb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"95mNb\" is the metastable state of the isotope \"niobium-95\" with a half-life of 3.61e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_96Nb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_96Nb.json index 1c32f9b12..60419bab3 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_96Nb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_96Nb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_96Nb", + "id": "surface_radioactivity_content_of_96Nb", "type": "standard_name", "name": "surface_radioactivity_content_of_96Nb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"96Nb\" is the isotope \"niobium-96\" with a half-life of 9.75e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_97Nb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_97Nb.json index f462d72a6..8fd2f663d 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_97Nb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_97Nb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_97Nb", + "id": "surface_radioactivity_content_of_97Nb", "type": "standard_name", "name": "surface_radioactivity_content_of_97Nb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"97Nb\" is the isotope \"niobium-97\" with a half-life of 5.11e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_97Zr.json b/data_descriptors/standard_name/surface_radioactivity_content_of_97Zr.json index a335996fd..e83e52138 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_97Zr.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_97Zr.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_97Zr", + "id": "surface_radioactivity_content_of_97Zr", "type": "standard_name", "name": "surface_radioactivity_content_of_97Zr", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Zr\" means the element \"zirconium\" and \"97Zr\" is the isotope \"zirconium-97\" with a half-life of 6.98e-01 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_97mNb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_97mNb.json index a860cf85b..85134bfe5 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_97mNb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_97mNb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_97mNb", + "id": "surface_radioactivity_content_of_97mNb", "type": "standard_name", "name": "surface_radioactivity_content_of_97mNb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"97mNb\" is the metastable state of the isotope \"niobium-97\" with a half-life of 6.27e-04 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_98Nb.json b/data_descriptors/standard_name/surface_radioactivity_content_of_98Nb.json index e73f7f32b..3a4effb6b 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_98Nb.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_98Nb.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_98Nb", + "id": "surface_radioactivity_content_of_98Nb", "type": "standard_name", "name": "surface_radioactivity_content_of_98Nb", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Nb\" means the element \"niobium\" and \"98Nb\" is the isotope \"niobium-98\" with a half-life of 3.53e-02 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_99Mo.json b/data_descriptors/standard_name/surface_radioactivity_content_of_99Mo.json index 4e25e91e1..686a63419 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_99Mo.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_99Mo.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_99Mo", + "id": "surface_radioactivity_content_of_99Mo", "type": "standard_name", "name": "surface_radioactivity_content_of_99Mo", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Mo\" means the element \"molybdenum\" and \"99Mo\" is the isotope \"molybdenum-99\" with a half-life of 2.78e+00 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_99Tc.json b/data_descriptors/standard_name/surface_radioactivity_content_of_99Tc.json index b13ecd4dc..9d83d03be 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_99Tc.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_99Tc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_99Tc", + "id": "surface_radioactivity_content_of_99Tc", "type": "standard_name", "name": "surface_radioactivity_content_of_99Tc", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tc\" means the element \"technetium\" and \"99Tc\" is the isotope \"technetium-99\" with a half-life of 7.79e+07 days.", diff --git a/data_descriptors/standard_name/surface_radioactivity_content_of_99mTc.json b/data_descriptors/standard_name/surface_radioactivity_content_of_99mTc.json index 53174b66b..0f1fde149 100644 --- a/data_descriptors/standard_name/surface_radioactivity_content_of_99mTc.json +++ b/data_descriptors/standard_name/surface_radioactivity_content_of_99mTc.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_radioactivity_content_of_99mTc", + "id": "surface_radioactivity_content_of_99mTc", "type": "standard_name", "name": "surface_radioactivity_content_of_99mTc", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Content\" indicates a quantity per unit area. \"Radioactivity\" means the number of radioactive decays of a material per second. \"Tc\" means the element \"technetium\" and \"99mTc\" is the metastable state of the isotope \"technetium-99\" with a half-life of 2.51e-01 days.", diff --git a/data_descriptors/standard_name/surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air.json b/data_descriptors/standard_name/surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air.json index 789bf78a0..b51a1ed5f 100644 --- a/data_descriptors/standard_name/surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air.json +++ b/data_descriptors/standard_name/surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air", + "id": "surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air", "type": "standard_name", "name": "surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The phrase \"ratio_of_X_to_Y\" means X/Y. Upwelling radiation is radiation from below. It does not mean \"net upward\". Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of angle_of_emergence. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In relation to satellite ocean color products the quantity named surface_ratio_of_upwelling_radiance_emerging_from_sea_water_to_downwelling_radiative_flux_in_air is sometimes called \"remote sensing reflectance\" and has a bidirectional dependence. The direction of the downwelling flux can be specified using a coordinate with the standard name angle_of_incidence.", diff --git a/data_descriptors/standard_name/surface_roughness_length.json b/data_descriptors/standard_name/surface_roughness_length.json index 22a312010..f6965ed7c 100644 --- a/data_descriptors/standard_name/surface_roughness_length.json +++ b/data_descriptors/standard_name/surface_roughness_length.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_roughness_length", + "id": "surface_roughness_length", "type": "standard_name", "name": "surface_roughness_length", "description": "The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_roughness_length_for_heat_in_air.json b/data_descriptors/standard_name/surface_roughness_length_for_heat_in_air.json index 047616f50..7ee287eb5 100644 --- a/data_descriptors/standard_name/surface_roughness_length_for_heat_in_air.json +++ b/data_descriptors/standard_name/surface_roughness_length_for_heat_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_roughness_length_for_heat_in_air", + "id": "surface_roughness_length_for_heat_in_air", "type": "standard_name", "name": "surface_roughness_length_for_heat_in_air", "description": "The height above the surface where the mean value of heat assumes its surface value when extrapolated along a logarithmic profile downward towards the surface. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_roughness_length_for_humidity_in_air.json b/data_descriptors/standard_name/surface_roughness_length_for_humidity_in_air.json index bbb05eebc..1370a3091 100644 --- a/data_descriptors/standard_name/surface_roughness_length_for_humidity_in_air.json +++ b/data_descriptors/standard_name/surface_roughness_length_for_humidity_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_roughness_length_for_humidity_in_air", + "id": "surface_roughness_length_for_humidity_in_air", "type": "standard_name", "name": "surface_roughness_length_for_humidity_in_air", "description": "The height above the surface where the mean value of humidity assumes its surface value when extrapolated along a logarithmic profile downward towards the surface. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_roughness_length_for_momentum_in_air.json b/data_descriptors/standard_name/surface_roughness_length_for_momentum_in_air.json index b15275e2b..d97521ed2 100644 --- a/data_descriptors/standard_name/surface_roughness_length_for_momentum_in_air.json +++ b/data_descriptors/standard_name/surface_roughness_length_for_momentum_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_roughness_length_for_momentum_in_air", + "id": "surface_roughness_length_for_momentum_in_air", "type": "standard_name", "name": "surface_roughness_length_for_momentum_in_air", "description": "The height above the displacement plane at which the mean wind becomes zero when extrapolating the logarithmic wind speed profile downward through the surface layer. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/surface_runoff_amount.json b/data_descriptors/standard_name/surface_runoff_amount.json index a7cdd0948..2648bc439 100644 --- a/data_descriptors/standard_name/surface_runoff_amount.json +++ b/data_descriptors/standard_name/surface_runoff_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_runoff_amount", + "id": "surface_runoff_amount", "type": "standard_name", "name": "surface_runoff_amount", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Amount\" means mass per unit area. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/surface_runoff_flux.json b/data_descriptors/standard_name/surface_runoff_flux.json index 85ef1d873..276cbf6f3 100644 --- a/data_descriptors/standard_name/surface_runoff_flux.json +++ b/data_descriptors/standard_name/surface_runoff_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_runoff_flux", + "id": "surface_runoff_flux", "type": "standard_name", "name": "surface_runoff_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_sea_water_x_velocity.json b/data_descriptors/standard_name/surface_sea_water_x_velocity.json index dd49c571a..0e7747dcd 100644 --- a/data_descriptors/standard_name/surface_sea_water_x_velocity.json +++ b/data_descriptors/standard_name/surface_sea_water_x_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_sea_water_x_velocity", + "id": "surface_sea_water_x_velocity", "type": "standard_name", "name": "surface_sea_water_x_velocity", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. Ocean currents are related to phenomena of different nature and processes, such as density currents, currents raised by the wind, tide, wave propagation, mass flow in estuaries, etc. This standard name refers to the sum of currents of all origins.", diff --git a/data_descriptors/standard_name/surface_sea_water_x_velocity_due_to_tides.json b/data_descriptors/standard_name/surface_sea_water_x_velocity_due_to_tides.json index e583b687e..0daca61ad 100644 --- a/data_descriptors/standard_name/surface_sea_water_x_velocity_due_to_tides.json +++ b/data_descriptors/standard_name/surface_sea_water_x_velocity_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_sea_water_x_velocity_due_to_tides", + "id": "surface_sea_water_x_velocity_due_to_tides", "type": "standard_name", "name": "surface_sea_water_x_velocity_due_to_tides", "description": "A velocity is a vector quantity. \"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are the rise and fall of sea levels caused by the combined effects of the gravitational forces exerted by the Moon and the Sun, and the rotation of the Earth. This rise in water level is accompanied by a horizontal movement of water called the tidal current.", diff --git a/data_descriptors/standard_name/surface_sea_water_y_velocity.json b/data_descriptors/standard_name/surface_sea_water_y_velocity.json index 5ef5765b9..7fa61e39d 100644 --- a/data_descriptors/standard_name/surface_sea_water_y_velocity.json +++ b/data_descriptors/standard_name/surface_sea_water_y_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_sea_water_y_velocity", + "id": "surface_sea_water_y_velocity", "type": "standard_name", "name": "surface_sea_water_y_velocity", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. Ocean currents are related to phenomena of different nature and processes, such as density currents, currents raised by the wind, tide, wave propagation, mass flow in estuaries, etc. This Standard Name refers to the sum of currents of all origins.", diff --git a/data_descriptors/standard_name/surface_sea_water_y_velocity_due_to_tides.json b/data_descriptors/standard_name/surface_sea_water_y_velocity_due_to_tides.json index fcf7d343c..8b0274449 100644 --- a/data_descriptors/standard_name/surface_sea_water_y_velocity_due_to_tides.json +++ b/data_descriptors/standard_name/surface_sea_water_y_velocity_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_sea_water_y_velocity_due_to_tides", + "id": "surface_sea_water_y_velocity_due_to_tides", "type": "standard_name", "name": "surface_sea_water_y_velocity_due_to_tides", "description": "A velocity is a vector quantity. \"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Tides are the rise and fall of sea levels caused by the combined effects of the gravitational forces exerted by the Moon and the Sun, and the rotation of the Earth. This rise in water level is accompanied by a horizontal movement of water called the tidal current.", diff --git a/data_descriptors/standard_name/surface_snow_amount.json b/data_descriptors/standard_name/surface_snow_amount.json index da0981571..e7ef62966 100644 --- a/data_descriptors/standard_name/surface_snow_amount.json +++ b/data_descriptors/standard_name/surface_snow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_amount", + "id": "surface_snow_amount", "type": "standard_name", "name": "surface_snow_amount", "description": "\"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/surface_snow_and_ice_melt_flux.json b/data_descriptors/standard_name/surface_snow_and_ice_melt_flux.json index 029803e8f..30e4cc2e9 100644 --- a/data_descriptors/standard_name/surface_snow_and_ice_melt_flux.json +++ b/data_descriptors/standard_name/surface_snow_and_ice_melt_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_and_ice_melt_flux", + "id": "surface_snow_and_ice_melt_flux", "type": "standard_name", "name": "surface_snow_and_ice_melt_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface snow and ice melt flux\" means the mass flux of all melting at the surface. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/surface_snow_and_ice_melt_heat_flux.json b/data_descriptors/standard_name/surface_snow_and_ice_melt_heat_flux.json index bb37cc011..57035e48b 100644 --- a/data_descriptors/standard_name/surface_snow_and_ice_melt_heat_flux.json +++ b/data_descriptors/standard_name/surface_snow_and_ice_melt_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_and_ice_melt_heat_flux", + "id": "surface_snow_and_ice_melt_heat_flux", "type": "standard_name", "name": "surface_snow_and_ice_melt_heat_flux", "description": "The snow and ice melt heat flux is the supply of latent heat which is melting snow and ice at freezing point. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_snow_and_ice_refreezing_flux.json b/data_descriptors/standard_name/surface_snow_and_ice_refreezing_flux.json index d2336d47b..ad196c7ff 100644 --- a/data_descriptors/standard_name/surface_snow_and_ice_refreezing_flux.json +++ b/data_descriptors/standard_name/surface_snow_and_ice_refreezing_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_and_ice_refreezing_flux", + "id": "surface_snow_and_ice_refreezing_flux", "type": "standard_name", "name": "surface_snow_and_ice_refreezing_flux", "description": "\"Surface snow and ice refreezing flux\" means the mass flux of surface meltwater which refreezes within the snow or firn. The surface called \"surface\" means the lower boundary of the atmosphere. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_snow_area_fraction.json b/data_descriptors/standard_name/surface_snow_area_fraction.json index 46b0a708a..0fe3da2cd 100644 --- a/data_descriptors/standard_name/surface_snow_area_fraction.json +++ b/data_descriptors/standard_name/surface_snow_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_area_fraction", + "id": "surface_snow_area_fraction", "type": "standard_name", "name": "surface_snow_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/surface_snow_binary_mask.json b/data_descriptors/standard_name/surface_snow_binary_mask.json index e94f09926..34961cc0b 100644 --- a/data_descriptors/standard_name/surface_snow_binary_mask.json +++ b/data_descriptors/standard_name/surface_snow_binary_mask.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_binary_mask", + "id": "surface_snow_binary_mask", "type": "standard_name", "name": "surface_snow_binary_mask", "description": "X\"_binary_mask\" has 1 where condition X is met, 0 elsewhere. The value is 1 where the snow cover area fraction is greater than a threshold, and 0 elsewhere. The threshold must be specified by associating a coordinate variable or scalar coordinate variable with the data variable and giving the coordinate variable a standard name of surface_snow_area_fraction. The values of the coordinate variable are the threshold values for the corresponding subarrays of the data variable. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/surface_snow_density.json b/data_descriptors/standard_name/surface_snow_density.json index 81ddceed6..5a3f21cf8 100644 --- a/data_descriptors/standard_name/surface_snow_density.json +++ b/data_descriptors/standard_name/surface_snow_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_density", + "id": "surface_snow_density", "type": "standard_name", "name": "surface_snow_density", "description": "Snow density is the density of the snow cover. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The density of a substance is its mass per unit volume.", diff --git a/data_descriptors/standard_name/surface_snow_melt_amount.json b/data_descriptors/standard_name/surface_snow_melt_amount.json index 9d3237c8b..f0ce24f9e 100644 --- a/data_descriptors/standard_name/surface_snow_melt_amount.json +++ b/data_descriptors/standard_name/surface_snow_melt_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_melt_amount", + "id": "surface_snow_melt_amount", "type": "standard_name", "name": "surface_snow_melt_amount", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The surface called \"surface\" means the lower boundary of the atmosphere. \"Amount\" means mass per unit area.", diff --git a/data_descriptors/standard_name/surface_snow_melt_and_sublimation_heat_flux.json b/data_descriptors/standard_name/surface_snow_melt_and_sublimation_heat_flux.json index ea645c39c..fd2df460f 100644 --- a/data_descriptors/standard_name/surface_snow_melt_and_sublimation_heat_flux.json +++ b/data_descriptors/standard_name/surface_snow_melt_and_sublimation_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_melt_and_sublimation_heat_flux", + "id": "surface_snow_melt_and_sublimation_heat_flux", "type": "standard_name", "name": "surface_snow_melt_and_sublimation_heat_flux", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. Sublimation is the conversion of solid into vapor. The snow melt and sublimation heat flux is the supply of latent heat which is converting snow to liquid water (melting) and water vapor (sublimation). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_snow_melt_flux.json b/data_descriptors/standard_name/surface_snow_melt_flux.json index 3ba426f8c..6fe054061 100644 --- a/data_descriptors/standard_name/surface_snow_melt_flux.json +++ b/data_descriptors/standard_name/surface_snow_melt_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_melt_flux", + "id": "surface_snow_melt_flux", "type": "standard_name", "name": "surface_snow_melt_flux", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The surface called \"surface\" means the lower boundary of the atmosphere. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_snow_melt_heat_flux.json b/data_descriptors/standard_name/surface_snow_melt_heat_flux.json index a7e439f0d..0e53ae0a5 100644 --- a/data_descriptors/standard_name/surface_snow_melt_heat_flux.json +++ b/data_descriptors/standard_name/surface_snow_melt_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_melt_heat_flux", + "id": "surface_snow_melt_heat_flux", "type": "standard_name", "name": "surface_snow_melt_heat_flux", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The snow melt heat flux is the supply of latent heat which is melting snow at freezing point. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_snow_sublimation_amount.json b/data_descriptors/standard_name/surface_snow_sublimation_amount.json index 419305ae9..356c349cc 100644 --- a/data_descriptors/standard_name/surface_snow_sublimation_amount.json +++ b/data_descriptors/standard_name/surface_snow_sublimation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_sublimation_amount", + "id": "surface_snow_sublimation_amount", "type": "standard_name", "name": "surface_snow_sublimation_amount", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. \"Amount\" means mass per unit area. Sublimation is the conversion of solid into vapor.", diff --git a/data_descriptors/standard_name/surface_snow_sublimation_heat_flux.json b/data_descriptors/standard_name/surface_snow_sublimation_heat_flux.json index 3e8b81710..9a348b55c 100644 --- a/data_descriptors/standard_name/surface_snow_sublimation_heat_flux.json +++ b/data_descriptors/standard_name/surface_snow_sublimation_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_sublimation_heat_flux", + "id": "surface_snow_sublimation_heat_flux", "type": "standard_name", "name": "surface_snow_sublimation_heat_flux", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. Sublimation is the conversion of solid into vapor. The snow sublimation heat flux is the supply of latent heat which is causing evaporation of snow to water vapor. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_snow_thickness.json b/data_descriptors/standard_name/surface_snow_thickness.json index e3c18d433..8295a2cde 100644 --- a/data_descriptors/standard_name/surface_snow_thickness.json +++ b/data_descriptors/standard_name/surface_snow_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_snow_thickness", + "id": "surface_snow_thickness", "type": "standard_name", "name": "surface_snow_thickness", "description": "Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. \"Thickness\" means the vertical extent of a layer. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", diff --git a/data_descriptors/standard_name/surface_specific_humidity.json b/data_descriptors/standard_name/surface_specific_humidity.json index 36185cdcf..6ffbdbbdb 100644 --- a/data_descriptors/standard_name/surface_specific_humidity.json +++ b/data_descriptors/standard_name/surface_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_specific_humidity", + "id": "surface_specific_humidity", "type": "standard_name", "name": "surface_specific_humidity", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/surface_temperature.json b/data_descriptors/standard_name/surface_temperature.json index 641989773..55b74b714 100644 --- a/data_descriptors/standard_name/surface_temperature.json +++ b/data_descriptors/standard_name/surface_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_temperature", + "id": "surface_temperature", "type": "standard_name", "name": "surface_temperature", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The surface temperature is the temperature at the interface, not the bulk temperature of the medium above or below. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies. In order to convert the units correctly, it is essential to know whether a temperature is on-scale or a difference. Therefore this standard strongly recommends that any variable whose units involve a temperature unit should also have a units_metadata attribute to make the distinction. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/surface_temperature_anomaly.json b/data_descriptors/standard_name/surface_temperature_anomaly.json index 47b40b336..fde55d0a0 100644 --- a/data_descriptors/standard_name/surface_temperature_anomaly.json +++ b/data_descriptors/standard_name/surface_temperature_anomaly.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_temperature_anomaly", + "id": "surface_temperature_anomaly", "type": "standard_name", "name": "surface_temperature_anomaly", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"anomaly\" means difference from climatology. The surface temperature is the (skin) temperature at the interface, not the bulk temperature of the medium above or below. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/surface_upward_eastward_stress_due_to_sea_surface_waves.json b/data_descriptors/standard_name/surface_upward_eastward_stress_due_to_sea_surface_waves.json index 48d611291..24fb298f1 100644 --- a/data_descriptors/standard_name/surface_upward_eastward_stress_due_to_sea_surface_waves.json +++ b/data_descriptors/standard_name/surface_upward_eastward_stress_due_to_sea_surface_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_eastward_stress_due_to_sea_surface_waves", + "id": "surface_upward_eastward_stress_due_to_sea_surface_waves", "type": "standard_name", "name": "surface_upward_eastward_stress_due_to_sea_surface_waves", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted at the surface. An upward stress is an upward flux of momentum into the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Eastward\" indicates a vector component which is positive when directed northward (negative southward). \"Upward eastward\" indicates the ZX component of a tensor. An upward eastward stress is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea surface waves\" means the stress associated with oscillatory motions of a wavy sea surface.", diff --git a/data_descriptors/standard_name/surface_upward_heat_flux_due_to_anthropogenic_energy_consumption.json b/data_descriptors/standard_name/surface_upward_heat_flux_due_to_anthropogenic_energy_consumption.json index b408bd2ee..cc0313ac9 100644 --- a/data_descriptors/standard_name/surface_upward_heat_flux_due_to_anthropogenic_energy_consumption.json +++ b/data_descriptors/standard_name/surface_upward_heat_flux_due_to_anthropogenic_energy_consumption.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_heat_flux_due_to_anthropogenic_energy_consumption", + "id": "surface_upward_heat_flux_due_to_anthropogenic_energy_consumption", "type": "standard_name", "name": "surface_upward_heat_flux_due_to_anthropogenic_energy_consumption", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The vertical heat flux in air is the sum of all heat fluxes i.e. radiative, latent and sensible. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Anthropogenic\" means influenced, caused, or created by human activity. The heat flux due to anthropogenic energy consumption results from non-renewable human primary energy consumption, including energy use by vehicles, commercial and residential buildings, industry, and power plants. Primary energy refers to energy in natural resources, fossil and non-fossil, before conversion into other forms, such as electricity.", diff --git a/data_descriptors/standard_name/surface_upward_heat_flux_in_air.json b/data_descriptors/standard_name/surface_upward_heat_flux_in_air.json index 07b392d48..1383dde73 100644 --- a/data_descriptors/standard_name/surface_upward_heat_flux_in_air.json +++ b/data_descriptors/standard_name/surface_upward_heat_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_heat_flux_in_air", + "id": "surface_upward_heat_flux_in_air", "type": "standard_name", "name": "surface_upward_heat_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The vertical heat flux in air is the sum of all heat fluxes i.e. radiative, latent and sensible. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upward_latent_heat_flux.json b/data_descriptors/standard_name/surface_upward_latent_heat_flux.json index 480f7de61..7a5c16669 100644 --- a/data_descriptors/standard_name/surface_upward_latent_heat_flux.json +++ b/data_descriptors/standard_name/surface_upward_latent_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_latent_heat_flux", + "id": "surface_upward_latent_heat_flux", "type": "standard_name", "name": "surface_upward_latent_heat_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_evaporation.json b/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_evaporation.json index b777c454b..afce52ac8 100644 --- a/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_evaporation.json +++ b/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_evaporation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_latent_heat_flux_due_to_evaporation", + "id": "surface_upward_latent_heat_flux_due_to_evaporation", "type": "standard_name", "name": "surface_upward_latent_heat_flux_due_to_evaporation", "description": "The quantity with standard name surface_upward_latent_heat_flux_due_to_evaporation does not include transpiration from vegetation. The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\"). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation).", diff --git a/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_sublimation.json b/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_sublimation.json index 6b338765e..889b86a98 100644 --- a/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_sublimation.json +++ b/data_descriptors/standard_name/surface_upward_latent_heat_flux_due_to_sublimation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_latent_heat_flux_due_to_sublimation", + "id": "surface_upward_latent_heat_flux_due_to_sublimation", "type": "standard_name", "name": "surface_upward_latent_heat_flux_due_to_sublimation", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sublimation is the conversion of solid into vapor.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_ammonia.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_ammonia.json index 7206c2d3a..52891b9eb 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_ammonia.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_ammonia.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_ammonia", + "id": "surface_upward_mass_flux_of_ammonia", "type": "standard_name", "name": "surface_upward_mass_flux_of_ammonia", "description": "Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration.json index 840bb0434..0edb408ec 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterotrophic respiration is respiration by heterotrophs (\"consumers\"), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs (\"producers\") do. Heterotrophic respiration goes on within both the soil and litter pools.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration.json index 1688f51e7..db242fd34 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration.json index 5db89a7f6..158997f1d 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterotrophic respiration is respiration by heterotrophs (\"consumers\"), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs (\"producers\") do. Heterotrophic respiration goes on within both the soil and litter pools.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration.json index d455e1b44..8694bff2c 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change.json index 91375a3b0..121763fea 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Anthropogenic\" means influenced, caused, or created by human activity. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products.json index 9e78d70ce..ce722cab6 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Anthropogenic\" means influenced, caused, or created by human activity. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change. The quantity with standard name surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products excludes the carbon dioxide flux into the atmosphere due to the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction. The standard name for the quantity that includes product decomposition is surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting.json index 999724079..2349a38fb 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The definition of \"crop\" is model dependent, for example, some models may include fruit trees, trees grown for timber or other types of agricultural and forestry planting as crops. Crop harvesting means the human activity of collecting plant materials for the purpose of turning them into forestry or agricultural products.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires.json index cdff33f71..f040f7ce3 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The term \"fires\" means all biomass fires, whether naturally occurring or ignited by humans. The quantity with standard name surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires is the sum of the quantities with standard names surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires and surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change.json index 32939936e..78a42d96c 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Fires excluding anthropogenic land use change\" means all natural fires and human ignited fires that are not associated with change of land use. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing.json index 4cff6c91e..4a8385e7c 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.json index 06b88a6dc..d2212bd5e 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Litter\" is dead plant material in or above the soil. The quantity with standard name surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires is the sum of the quantities with standard names surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires and surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires.json index e7080cb00..543b267ad 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Natural fires\" means burning of biomass, whether living or dead, excluding fires ignited by humans, e.g. for agricultural purposes.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources.json index 6989978fb..22ece82d7 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires.json index 8e1b9ca8d..7b41b7bb8 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The quantity with standard name surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires is the sum of the quantities with standard names surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires and surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration.json index 615f390fc..2339943e9 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterotrophic respiration is respiration by heterotrophs (\"consumers\"), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs (\"producers\") do. Heterotrophic respiration goes on both above and within the soil.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration.json index d3ad84bb3..fb48e9b83 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth.json index d090757df..aef42df23 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance.json index 3e3294b32..a81480c59 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves.json index 6ef480f62..eeb2feb44 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. Plants which photosynthesise are autotrophs i.e. \"producers\" of the biomass which they respire from inorganic precursors using sunlight for energy.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter.json index 1405968c7..f63e5068c 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide. \"Miscellaneous living matter\" means all those parts of plants that are not leaf, stem, root or other separately named components.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots.json index 8071c0da7..4fe58f048 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. Plants which photosynthesise are autotrophs i.e. \"producers\" of the biomass which they respire from inorganic precursors using sunlight for energy.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems.json index ba84cd10c..65a6a15d8 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Plant respiration is the sum of respiration by parts of plants both above and below the soil. Plants which photosynthesise are autotrophs i.e. \"producers\" of the biomass which they respire from inorganic precursors using sunlight for energy. The stem of a plant is the axis that bears buds and shoots with leaves and, at its basal end, roots. Its function is to carry water and nutrients. Examples include the stalk of a plant or the main trunk of a tree.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil.json index 56144cef8..8db1073a5 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil", + "id": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_respiration_in_soil", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for carbon dioxide is CO2. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Soil respiration is the sum of respiration in the soil by animals and decomposers of litter (heterotrophs or \"consumers\"), which have not produced the biomass they respire, and respiration by the roots of plants (autotrophs or \"producers\"), which have themselves produced the biomass they respire.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter.json index 838fd53dd..7c4450a2c 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter", + "id": "surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Litter\" is dead plant material in or above the soil. Heterotrophic respiration is respiration by heterotrophs (\"consumers\"), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs (\"producers\") do. Heterotrophic respiration goes on within both the soil and litter pools.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil.json index db8eea114..5ed6c0f31 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil", + "id": "surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil", "type": "standard_name", "name": "surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterotrophic respiration is respiration by heterotrophs (\"consumers\"), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs (\"producers\") do. Heterotrophic respiration goes on within both the soil and litter pools.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_fires.json index c9adb358c..31796a72c 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_fires", + "id": "surface_upward_mass_flux_of_methane_due_to_emission_from_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_methane_due_to_emission_from_fires", "description": "Methane emitted from the surface, generated by biomass burning (fires). Positive direction upwards. The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The term \"fires\" means all biomass fires, whether naturally occurring or ignited by humans. The precise conditions under which fires produce and consume methane can vary between models.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals.json index f6c9d85e0..654cc7113 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals", + "id": "surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals", "type": "standard_name", "name": "surface_upward_mass_flux_of_methane_due_to_emission_from_herbivorous_mammals", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Herbivores are animals that feed on vegetation. Mammals are any vertebrates within the class Mammalia. Examples of large herbivorous mammals include cows, elks, and buffalos. These animals eat grass, tree bark, aquatic vegetation, and shrubby growth. Herbivores can also be medium-sized animals such as sheep and goats, which eat shrubby vegetation and grasses. Small herbivores include rabbits, chipmunks, squirrels, and mice. The precise conditions under which herbivorous mammals produce and consume methane can vary between models.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_termites.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_termites.json index d82f23fc3..af351ac21 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_termites.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_termites.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_termites", + "id": "surface_upward_mass_flux_of_methane_due_to_emission_from_termites", "type": "standard_name", "name": "surface_upward_mass_flux_of_methane_due_to_emission_from_termites", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Termites belong to any of a group of cellulose-eating insects, the social system of which shows remarkable parallels with those of ants and bees, although it has evolved independently. The precise conditions under which termites produce and consume methane can vary between models.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production.json index b0fc82cd2..789a4b6bc 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production", + "id": "surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production", "type": "standard_name", "name": "surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for methane is CH4. The mass is the total mass of the molecules. The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Wetlands are areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season. The precise conditions under which wetlands produce and consume methane can vary between models.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen.json index b0a2e57d8..27dbc82e8 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen", + "id": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen", "type": "standard_name", "name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. he phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires.json index 9bf946374..3e670e8c8 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires", + "id": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"All land processes\" means plant and soil respiration, photosynthesis, animal grazing, crop harvesting, natural fires and anthropogenic land use change.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires.json index bc48146e7..c25e59c87 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires", + "id": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires", "type": "standard_name", "name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The term \"fires\" means all biomass fires, whether naturally occurring or ignited by humans.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json index d8b092094..52176ed78 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", + "id": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "type": "standard_name", "name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json index 82ffd6d06..355a6ab22 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", + "id": "surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "type": "standard_name", "name": "surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for nitrous oxide is N2O. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide. \"Litter\" is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between \"fine\" and \"coarse\" is model dependent.", diff --git a/data_descriptors/standard_name/surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json b/data_descriptors/standard_name/surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json index b7c942e3d..01e0c0450 100644 --- a/data_descriptors/standard_name/surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json +++ b/data_descriptors/standard_name/surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", + "id": "surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "type": "standard_name", "name": "surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nox\" means a combination of two radical species containing nitrogen and oxygen NO+NO2. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"Litter\" is dead plant material in or above the soil.", diff --git a/data_descriptors/standard_name/surface_upward_mole_flux_of_carbon_dioxide.json b/data_descriptors/standard_name/surface_upward_mole_flux_of_carbon_dioxide.json index 1ea0f117f..ec57281e9 100644 --- a/data_descriptors/standard_name/surface_upward_mole_flux_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/surface_upward_mole_flux_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mole_flux_of_carbon_dioxide", + "id": "surface_upward_mole_flux_of_carbon_dioxide", "type": "standard_name", "name": "surface_upward_mole_flux_of_carbon_dioxide", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The surface called \"surface\" means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. The standard name surface_downward_mole_flux_of_carbon_dioxide should be used to label data in which the flux is positive when directed downward. The standard name \"surface_carbon_dioxide_mole_flux\" is deprecated because it does not specify in which direction the flux is positive. Any data having the standard name \"surface_carbon_dioxide_mole_flux\" should be examined carefully to determine which sign convention was used.", diff --git a/data_descriptors/standard_name/surface_upward_mole_flux_of_dimethyl_sulfide.json b/data_descriptors/standard_name/surface_upward_mole_flux_of_dimethyl_sulfide.json index 1f671b9b8..4cda12f9b 100644 --- a/data_descriptors/standard_name/surface_upward_mole_flux_of_dimethyl_sulfide.json +++ b/data_descriptors/standard_name/surface_upward_mole_flux_of_dimethyl_sulfide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_mole_flux_of_dimethyl_sulfide", + "id": "surface_upward_mole_flux_of_dimethyl_sulfide", "type": "standard_name", "name": "surface_upward_mole_flux_of_dimethyl_sulfide", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/surface_upward_northward_stress_due_to_sea_surface_waves.json b/data_descriptors/standard_name/surface_upward_northward_stress_due_to_sea_surface_waves.json index 2bf562810..ad8e47dc1 100644 --- a/data_descriptors/standard_name/surface_upward_northward_stress_due_to_sea_surface_waves.json +++ b/data_descriptors/standard_name/surface_upward_northward_stress_due_to_sea_surface_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_northward_stress_due_to_sea_surface_waves", + "id": "surface_upward_northward_stress_due_to_sea_surface_waves", "type": "standard_name", "name": "surface_upward_northward_stress_due_to_sea_surface_waves", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Surface stress\" means the shear stress (force per unit area) exerted at the surface. An upward stress is an upward flux of momentum into the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Upward northward\" indicates the ZY component of a tensor. An upward northward stress is an upward flux of northward momentum, which accelerates the upper medium northward and the lower medium southward. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea surface waves\" means the stress associated with oscillatory motions of a wavy sea surface.", diff --git a/data_descriptors/standard_name/surface_upward_sensible_heat_flux.json b/data_descriptors/standard_name/surface_upward_sensible_heat_flux.json index 57182fba1..3ee1b29ca 100644 --- a/data_descriptors/standard_name/surface_upward_sensible_heat_flux.json +++ b/data_descriptors/standard_name/surface_upward_sensible_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_sensible_heat_flux", + "id": "surface_upward_sensible_heat_flux", "type": "standard_name", "name": "surface_upward_sensible_heat_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The surface sensible heat flux, also called \"turbulent\" heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", diff --git a/data_descriptors/standard_name/surface_upward_water_flux.json b/data_descriptors/standard_name/surface_upward_water_flux.json index 65034750d..d630c8656 100644 --- a/data_descriptors/standard_name/surface_upward_water_flux.json +++ b/data_descriptors/standard_name/surface_upward_water_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_water_flux", + "id": "surface_upward_water_flux", "type": "standard_name", "name": "surface_upward_water_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Water\" means water in all phases, including frozen i.e. ice and snow. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The surface water flux is the result of precipitation and evaporation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upward_water_vapor_flux_in_air.json b/data_descriptors/standard_name/surface_upward_water_vapor_flux_in_air.json index 22e7af7b7..1ebf3a366 100644 --- a/data_descriptors/standard_name/surface_upward_water_vapor_flux_in_air.json +++ b/data_descriptors/standard_name/surface_upward_water_vapor_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upward_water_vapor_flux_in_air", + "id": "surface_upward_water_vapor_flux_in_air", "type": "standard_name", "name": "surface_upward_water_vapor_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air.json b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air.json index ed84e2273..fae6b5900 100644 --- a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_longwave_flux_in_air", + "id": "surface_upwelling_longwave_flux_in_air", "type": "standard_name", "name": "surface_upwelling_longwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky.json index d22b5d069..cff7a8e8f 100644 --- a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky", + "id": "surface_upwelling_longwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "surface_upwelling_longwave_flux_in_air_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 5c2230aaf..1e7708632 100644 --- a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. The 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index 7c9e6fc0a..2db2643de 100644 --- a/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_upwelling_photosynthetic_photon_flux_in_air.json b/data_descriptors/standard_name/surface_upwelling_photosynthetic_photon_flux_in_air.json index f6323006b..e1514cb2b 100644 --- a/data_descriptors/standard_name/surface_upwelling_photosynthetic_photon_flux_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_photosynthetic_photon_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_photosynthetic_photon_flux_in_air", + "id": "surface_upwelling_photosynthetic_photon_flux_in_air", "type": "standard_name", "name": "surface_upwelling_photosynthetic_photon_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. \"Photosynthetic\" radiation is the part of the spectrum which is used in photosynthesis e.g. 400-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_in_air.json b/data_descriptors/standard_name/surface_upwelling_radiance_in_air.json index 825f87825..eaeeec825 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_in_air", + "id": "surface_upwelling_radiance_in_air", "type": "standard_name", "name": "surface_upwelling_radiance_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_in_air_emerging_from_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiance_in_air_emerging_from_sea_water.json index 7c6a18416..90ac3d945 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_in_air_emerging_from_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_in_air_emerging_from_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_in_air_emerging_from_sea_water", + "id": "surface_upwelling_radiance_in_air_emerging_from_sea_water", "type": "standard_name", "name": "surface_upwelling_radiance_in_air_emerging_from_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_in_air_reflected_by_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiance_in_air_reflected_by_sea_water.json index 4d66a6d9e..9cb132412 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_in_air_reflected_by_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_in_air_reflected_by_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_in_air_reflected_by_sea_water", + "id": "surface_upwelling_radiance_in_air_reflected_by_sea_water", "type": "standard_name", "name": "surface_upwelling_radiance_in_air_reflected_by_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_in_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiance_in_sea_water.json index 01be2d89a..260cfe889 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_in_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_in_sea_water", + "id": "surface_upwelling_radiance_in_sea_water", "type": "standard_name", "name": "surface_upwelling_radiance_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air.json index b10daac74..c00fc17c0 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air", + "id": "surface_upwelling_radiance_per_unit_wavelength_in_air", "type": "standard_name", "name": "surface_upwelling_radiance_per_unit_wavelength_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water.json index da8f127d8..a079d4dff 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water", + "id": "surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water", "type": "standard_name", "name": "surface_upwelling_radiance_per_unit_wavelength_in_air_emerging_from_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water.json index 3f37022b8..7bd07ac27 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water", + "id": "surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water", "type": "standard_name", "name": "surface_upwelling_radiance_per_unit_wavelength_in_air_reflected_by_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_sea_water.json index 6aedbb5d3..aad7b1e19 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiance_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiance_per_unit_wavelength_in_sea_water", + "id": "surface_upwelling_radiance_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_upwelling_radiance_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_air.json index 944e906c2..8b3c1ff39 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_air", + "id": "surface_upwelling_radiative_flux_per_unit_wavelength_in_air", "type": "standard_name", "name": "surface_upwelling_radiative_flux_per_unit_wavelength_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json index 3f3ae50ba..3f83241a0 100644 --- a/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water", + "id": "surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "surface_upwelling_radiative_flux_per_unit_wavelength_in_sea_water", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air.json index d68075a34..229b8019a 100644 --- a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_shortwave_flux_in_air", + "id": "surface_upwelling_shortwave_flux_in_air", "type": "standard_name", "name": "surface_upwelling_shortwave_flux_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The term \"shortwave\" means shortwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky.json index 531c5e910..6c0daea19 100644 --- a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", + "id": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. The term \"shortwave\" means shortwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json index 3ee52895a..8f6e44df4 100644 --- a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json +++ b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", + "id": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "type": "standard_name", "name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 128811458..7d60a8152 100644 --- a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index ecd5b1726..d783b55a0 100644 --- a/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "surface_upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/surface_water_amount.json b/data_descriptors/standard_name/surface_water_amount.json index f2ae34f56..6b8d639a3 100644 --- a/data_descriptors/standard_name/surface_water_amount.json +++ b/data_descriptors/standard_name/surface_water_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_water_amount", + "id": "surface_water_amount", "type": "standard_name", "name": "surface_water_amount", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Amount\" means mass per unit area. \"Water\" means water in all phases, including frozen i.e. ice and snow. Surface amount refers to the amount on the ground, excluding that on the plant or vegetation canopy.", diff --git a/data_descriptors/standard_name/surface_water_evaporation_flux.json b/data_descriptors/standard_name/surface_water_evaporation_flux.json index aad32b9aa..799c71bc9 100644 --- a/data_descriptors/standard_name/surface_water_evaporation_flux.json +++ b/data_descriptors/standard_name/surface_water_evaporation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/surface_water_evaporation_flux", + "id": "surface_water_evaporation_flux", "type": "standard_name", "name": "surface_water_evaporation_flux", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"Water\" means water in all phases, including frozen i.e. ice and snow. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\"). The quantity with standard name surface_water_evaporation_flux does not include transpiration from vegetation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", diff --git a/data_descriptors/standard_name/syntax_test_quality_flag.json b/data_descriptors/standard_name/syntax_test_quality_flag.json index 49e314121..31d619f0c 100644 --- a/data_descriptors/standard_name/syntax_test_quality_flag.json +++ b/data_descriptors/standard_name/syntax_test_quality_flag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/syntax_test_quality_flag", + "id": "syntax_test_quality_flag", "type": "standard_name", "name": "syntax_test_quality_flag", "description": "A quality flag that reports the result of the Syntax test, which checks that the data contain no indicators of flawed transmission. The linkage between the data variable and this variable is achieved using the ancillary_variables attribute. There are standard names for other specific quality tests which take the form of X_quality_flag. Quality information that does not match any of the specific quantities should be given the more general standard name of quality_flag.", diff --git a/data_descriptors/standard_name/temperature_at_base_of_ice_sheet_model.json b/data_descriptors/standard_name/temperature_at_base_of_ice_sheet_model.json index aa4688c96..c83d5a846 100644 --- a/data_descriptors/standard_name/temperature_at_base_of_ice_sheet_model.json +++ b/data_descriptors/standard_name/temperature_at_base_of_ice_sheet_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_at_base_of_ice_sheet_model", + "id": "temperature_at_base_of_ice_sheet_model", "type": "standard_name", "name": "temperature_at_base_of_ice_sheet_model", "description": "The quantity with standard name temperature_at_base_of_ice_sheet_model is the lower boundary temperature that is used to force ice sheet models. Beneath ice shelves it is the temperature at the ice-ocean interface. Beneath grounded ice, it is the temperature at the ice-bedrock interface. In all instances the temperature is that of the interface itself and not that of the medium above or below the interface. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_at_top_of_ice_sheet_model.json b/data_descriptors/standard_name/temperature_at_top_of_ice_sheet_model.json index c48a8a050..75a5c5358 100644 --- a/data_descriptors/standard_name/temperature_at_top_of_ice_sheet_model.json +++ b/data_descriptors/standard_name/temperature_at_top_of_ice_sheet_model.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_at_top_of_ice_sheet_model", + "id": "temperature_at_top_of_ice_sheet_model", "type": "standard_name", "name": "temperature_at_top_of_ice_sheet_model", "description": "The quantity with standard name temperature_at_top_of_ice_sheet_model is the upper boundary temperature that is used to force ice sheet models. It is the temperature at the interface between the ice sheet and the overlying medium which may be snow or the atmosphere. In all instances the temperature is that of the interface itself and not that of the medium above or below the interface. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically.json b/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically.json index dfd7eb3db..ed090b362 100644 --- a/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically.json +++ b/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically", + "id": "temperature_difference_between_ambient_air_and_air_lifted_adiabatically", "type": "standard_name", "name": "temperature_difference_between_ambient_air_and_air_lifted_adiabatically", "description": "This quantity is defined as the temperature difference between a parcel of air lifted adiabatically from a starting air pressure to a finishing air pressure in the troposphere and the ambient air temperature at the finishing air pressure in the troposphere. It is often called the lifted index (LI) and provides a measure of the instability of the atmosphere. The air parcel is \"lifted\" by moving the air parcel from the starting air pressure to the Lifting Condensation Level (dry adiabatically) and then from the Lifting Condensation Level to the finishing air pressure (wet adiabatically). Air temperature is the bulk temperature of the air. Coordinate variables of original_air_pressure_of_lifted_parcel and final_air_pressure_of_lifted_parcel should be specified to indicate the specific air pressures at which the parcel lifting starts (starting air pressure) and the temperature difference is calculated at (finishing air pressure), respectively. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface.json b/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface.json index e40160f10..d02987a35 100644 --- a/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface.json +++ b/data_descriptors/standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface", + "id": "temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface", "type": "standard_name", "name": "temperature_difference_between_ambient_air_and_air_lifted_adiabatically_from_the_surface", "description": "This quantity is defined as the temperature difference between a parcel of air lifted adiabatically from the surface to a finishing air pressure in the troposphere and the ambient air temperature at the finishing air pressure in the troposphere. It is often called the lifted index (LI) and provides a measure of the instability of the atmosphere. The air parcel is \"lifted\" by moving the air parcel from the surface to the Lifting Condensation Level (dry adiabatically) and then from the Lifting Condensation Level to the finishing air pressure (wet adiabatically). Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The term \"surface\" means the lower boundary of the atmosphere. A coordinate variable of final_air_pressure_of_lifted_parcel should be specified to indicate the specific air pressure that the temperature difference is calculated at. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water.json b/data_descriptors/standard_name/temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water.json index 93212ed8a..8513c4932 100644 --- a/data_descriptors/standard_name/temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water.json +++ b/data_descriptors/standard_name/temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water", + "id": "temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water", "type": "standard_name", "name": "temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water", "description": "Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) The quantity with standard name temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water is the heat energy carried by the transfer of water away from the liquid ocean through the process of evaporation. It is distinct from the transfer of latent heat and is calculated relative to the heat that would be transported by water evaporating at zero degrees Celsius. It is calculated as the product QevapCpTevap, where Qevap is the mass flux of evaporating water (kg m-2 s-1), Cp is the specific heat capacity of water and Tevap is the temperature in degrees Celsius of the evaporating water. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water.json b/data_descriptors/standard_name/temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water.json index f8301ed73..9d2a8eeab 100644 --- a/data_descriptors/standard_name/temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water.json +++ b/data_descriptors/standard_name/temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water", + "id": "temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water", "type": "standard_name", "name": "temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water", "description": "The quantity with standard name temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water is the heat energy carried by rainfall entering the sea at the sea surface. It is calculated relative to the heat that would be carried by rainfall entering the sea at zero degrees Celsius. It is calculated as the product QrainCpTrain, where Qrain is the mass flux of rainfall entering the sea (kg m-2 s-1), Cp is the specific heat capacity of water and Train is the temperature in degrees Celsius of the rain water entering the sea surface. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water.json b/data_descriptors/standard_name/temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water.json index 181f04a87..2df582e49 100644 --- a/data_descriptors/standard_name/temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water.json +++ b/data_descriptors/standard_name/temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water", + "id": "temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water", "type": "standard_name", "name": "temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water", "description": "The quantity with standard name temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water is the heat carried by the transfer of water into the liquid ocean by the process of runoff. This quantity additionally includes melt water from sea ice and icebergs. It is calculated relative to the heat that would be transported by runoff water entering the sea at zero degrees Celsius. It is calculated as the product QrunoffCpTrunoff, where Q runoff is the mass flux of liquid runoff entering the sea water (kg m-2 s-1), Cp is the specific heat capacity of water, and Trunoff is the temperature in degrees Celsius of the runoff water. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/temperature_in_ground.json b/data_descriptors/standard_name/temperature_in_ground.json index 10f2032b2..ddf225807 100644 --- a/data_descriptors/standard_name/temperature_in_ground.json +++ b/data_descriptors/standard_name/temperature_in_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_in_ground", + "id": "temperature_in_ground", "type": "standard_name", "name": "temperature_in_ground", "description": "The temperature at any given depth (or in a layer) below the surface of the ground, excluding surficial snow and ice (but not permafrost or soil). For temperatures in surface lying snow and ice, the more specific standard names temperature_in_surface_snow and land_ice_temperature should be used. For temperatures measured or modelled specifically for the soil layer (the near-surface layer where plants sink their roots) the standard name soil_temperature should be used. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_in_surface_snow.json b/data_descriptors/standard_name/temperature_in_surface_snow.json index 38aae9fb9..a4b442a7d 100644 --- a/data_descriptors/standard_name/temperature_in_surface_snow.json +++ b/data_descriptors/standard_name/temperature_in_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_in_surface_snow", + "id": "temperature_in_surface_snow", "type": "standard_name", "name": "temperature_in_surface_snow", "description": "\"Temperature in surface snow\" is the bulk temperature of the snow, not the surface (skin) temperature. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_of_analysis_of_sea_water.json b/data_descriptors/standard_name/temperature_of_analysis_of_sea_water.json index d382da09a..d71966289 100644 --- a/data_descriptors/standard_name/temperature_of_analysis_of_sea_water.json +++ b/data_descriptors/standard_name/temperature_of_analysis_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_of_analysis_of_sea_water", + "id": "temperature_of_analysis_of_sea_water", "type": "standard_name", "name": "temperature_of_analysis_of_sea_water", "description": "The temperature_of_analysis_of_sea_water is the reference temperature for the effects of temperature on the measurement of another variable. This temperature should be measured, but may have been calculated, or assumed. For example, the temperature of the sample when measuring pH, or the temperature of equilibration in the case of dissolved gases. The linkage between the data variable and the variable with a standard_name of temperature_of_analysis_of_sea_water is achieved using the ancillary_variables attribute on the data variable. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/temperature_of_sensor_for_oxygen_in_sea_water.json b/data_descriptors/standard_name/temperature_of_sensor_for_oxygen_in_sea_water.json index 93583b88c..cf49b5d1d 100644 --- a/data_descriptors/standard_name/temperature_of_sensor_for_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/temperature_of_sensor_for_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/temperature_of_sensor_for_oxygen_in_sea_water", + "id": "temperature_of_sensor_for_oxygen_in_sea_water", "type": "standard_name", "name": "temperature_of_sensor_for_oxygen_in_sea_water", "description": "Temperature_of_sensor_for_oxygen_in_sea_water is the instrument temperature used in calculating the concentration of oxygen in sea water; it is not a measurement of the ambient water temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_density.json b/data_descriptors/standard_name/tendency_of_air_density.json index ab3d7eaee..5edceb216 100644 --- a/data_descriptors/standard_name/tendency_of_air_density.json +++ b/data_descriptors/standard_name/tendency_of_air_density.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_density", + "id": "tendency_of_air_density", "type": "standard_name", "name": "tendency_of_air_density", "description": "\"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_air_pressure.json b/data_descriptors/standard_name/tendency_of_air_pressure.json index 84b5213e5..3f868afd6 100644 --- a/data_descriptors/standard_name/tendency_of_air_pressure.json +++ b/data_descriptors/standard_name/tendency_of_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_pressure", + "id": "tendency_of_air_pressure", "type": "standard_name", "name": "tendency_of_air_pressure", "description": "\"tendency_of_X\" means derivative of X with respect to time. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature.json b/data_descriptors/standard_name/tendency_of_air_temperature.json index df673ec2c..691960316 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature", + "id": "tendency_of_air_temperature", "type": "standard_name", "name": "tendency_of_air_temperature", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_advection.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_advection.json index a48bc525a..90a4f7e4c 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_advection", + "id": "tendency_of_air_temperature_due_to_advection", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_boundary_layer_mixing.json index e430fbfee..99e508cf9 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_boundary_layer_mixing", + "id": "tendency_of_air_temperature_due_to_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm). It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_convection.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_convection.json index f1b26c81b..f8db5d7ba 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_convection", + "id": "tendency_of_air_temperature_due_to_convection", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_convection", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diabatic_processes.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diabatic_processes.json index 8a68091b9..b6916b6e4 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diabatic_processes.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diabatic_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_diabatic_processes", + "id": "tendency_of_air_temperature_due_to_diabatic_processes", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_diabatic_processes", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diffusion.json index a94e27d1f..e637b9ea4 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_diffusion", + "id": "tendency_of_air_temperature_due_to_diffusion", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves.json index afed94899..082d16b67 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves", + "id": "tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Nonorographic\" gravity waves refer to gravity waves which are not generated by flow over orography. The dissipation of gravity waves generates heating through an eddy heat flux convergence and through a viscous stress term. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves.json index 2e61e436e..1001011e9 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves", + "id": "tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Orographic gravity waves\" refer to gravity waves which are generated by flow over orography. The dissipation of gravity waves generates heating through an eddy heat flux convergence and through a viscous stress term. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dry_convection.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dry_convection.json index 380aa0ab7..80a98b03f 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dry_convection.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_dry_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_dry_convection", + "id": "tendency_of_air_temperature_due_to_dry_convection", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_dry_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating.json index 5c5199fde..4dd551c8b 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_longwave_heating", + "id": "tendency_of_air_temperature_due_to_longwave_heating", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_longwave_heating", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"longwave\" means longwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky.json index daa4cd47b..596869726 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky", + "id": "tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"tendency_of_X\" means derivative of X with respect to time. \"longwave\" means longwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles.json index d9774c94c..85b6b2696 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles", + "id": "tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The term \"longwave\" means longwave radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_model_physics.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_model_physics.json index fec5f3ba3..8b9fd6677 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_model_physics.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_model_physics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_model_physics", + "id": "tendency_of_air_temperature_due_to_model_physics", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_model_physics", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_moist_convection.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_moist_convection.json index de06ac974..d8ff1c1c1 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_moist_convection.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_moist_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_moist_convection", + "id": "tendency_of_air_temperature_due_to_moist_convection", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_moist_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_radiative_heating.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_radiative_heating.json index 6d67d2474..98b82f3b5 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_radiative_heating.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_radiative_heating.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_radiative_heating", + "id": "tendency_of_air_temperature_due_to_radiative_heating", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_radiative_heating", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating.json index 58ac4334e..8ad2ce73b 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_shortwave_heating", + "id": "tendency_of_air_temperature_due_to_shortwave_heating", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_shortwave_heating", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"shortwave\" means shortwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky.json index 80b128f6c..9267a965d 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky", + "id": "tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"tendency_of_X\" means derivative of X with respect to time. \"shortwave\" means shortwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles.json index 4f155a171..959896b36 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles", + "id": "tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The term \"shortwave\" means shortwave radiation. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation.json index 64e0d27bf..787c53976 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation", + "id": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. A variable with the standard name tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation should contain net latent heating effects of all processes which convert stratiform clouds and precipitation between water vapor, liquid or ice phases. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json index 6cbd2a197..56f878164 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", + "id": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm). It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_precipitation.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_precipitation.json index 771f2f42a..90f3cc18d 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_precipitation.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_stratiform_precipitation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_stratiform_precipitation", + "id": "tendency_of_air_temperature_due_to_stratiform_precipitation", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_stratiform_precipitation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_turbulence.json b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_turbulence.json index 2de33acde..8fddbe5aa 100644 --- a/data_descriptors/standard_name/tendency_of_air_temperature_due_to_turbulence.json +++ b/data_descriptors/standard_name/tendency_of_air_temperature_due_to_turbulence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_air_temperature_due_to_turbulence", + "id": "tendency_of_air_temperature_due_to_turbulence", "type": "standard_name", "name": "tendency_of_air_temperature_due_to_turbulence", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_dry_energy_content.json b/data_descriptors/standard_name/tendency_of_atmosphere_dry_energy_content.json index b6d839e19..19888fe8f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_dry_energy_content.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_dry_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_dry_energy_content", + "id": "tendency_of_atmosphere_dry_energy_content", "type": "standard_name", "name": "tendency_of_atmosphere_dry_energy_content", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_enthalpy_content_due_to_advection.json b/data_descriptors/standard_name/tendency_of_atmosphere_enthalpy_content_due_to_advection.json index 5ac945168..cbb0dc722 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_enthalpy_content_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_enthalpy_content_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_enthalpy_content_due_to_advection", + "id": "tendency_of_atmosphere_enthalpy_content_due_to_advection", "type": "standard_name", "name": "tendency_of_atmosphere_enthalpy_content_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_kinetic_energy_content_due_to_advection.json b/data_descriptors/standard_name/tendency_of_atmosphere_kinetic_energy_content_due_to_advection.json index 910c87e27..1c62c9b0a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_kinetic_energy_content_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_kinetic_energy_content_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_kinetic_energy_content_due_to_advection", + "id": "tendency_of_atmosphere_kinetic_energy_content_due_to_advection", "type": "standard_name", "name": "tendency_of_atmosphere_kinetic_energy_content_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition.json index 9a6056ce6..5331e1fb1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for acetaldehyde is CH3CHO. The IUPAC name for acetaldehyde is ethanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission.json index 6ae54581c..bf35f3acc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for acetaldehyde is CH3CHO. The IUPAC name for acetaldehyde is ethanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition.json index 68dd33baa..83b0568b9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_acetaldehyde_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for acetaldehyde is CH3CHO. The IUPAC name for acetaldehyde is ethanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition.json index 8d918eb96..e7f69bf34 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition.json index ac92dcf87..ad116dda9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_acetic_acid_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Wet deposition\" means deposition by precipitation. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition.json index f11fdb9ab..0d0424988 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_aceto_nitrile_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetone_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetone_due_to_emission.json index 09449da87..b01dc770d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetone_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_acetone_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_acetone_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_acetone_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_acetone_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. Acetone is an organic molecule with the chemical formula CH3CH3CO. The IUPAC name for acetone is propan-2-one. Acetone is a member of the group of organic compounds known as ketones. There are standard names for the ketone group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production.json index fdb945fdd..73572070d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning.json index 60d6dd1a5..5aa7a3c63 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution.json index 37da47385..fdc035080 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires.json index d2117e34d..c3559ea63 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion.json index 674e509fc..9f3ea5bae 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion.json index a8b211255..d0982fe06 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires.json index d05d075bd..a8e6ff5d5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use.json index b4c8148de..c2eadc803 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal.json index f9c0c9d20..bc496da1d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alcohols_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Alcohols include all organic compounds with an alcoholic (OH) group. In standard names \"alcohols\" is the term used to describe the group of chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition.json index 9c8da0ec4..3f76f4288 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_aldehydes_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. Aldehydes are organic compounds with a CHO group; \"aldehydes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual aldehyde species, e.g., formaldehyde and acetyladehyde.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition.json index 69d54afd7..30188ed0a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_aldehydes_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. Aldehydes are organic compounds with a CHO group; \"aldehydes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual aldehyde species, e.g., formaldehyde and acetyladehyde.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission.json index 3b5cbc990..d44665c95 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alkanes_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. Alkanes are saturated hydrocarbons, i.e. they do not contain any chemical double bonds. \"Hydrocarbon\" means a compound containing hydrogen and carbon. Alkanes contain only hydrogen and carbon combined in the general proportions C(n)H(2n+2); \"alkanes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkane species, e.g., methane and ethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission.json index 45e3edac0..a9780de1a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alkenes_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. Alkenes are unsaturated hydrocarbons as they contain chemical double bonds between adjacent carbon atoms. \"Hydrocarbon\" means a compound containing hydrogen and carbon. Alkenes contain only hydrogen and carbon combined in the general proportions C(n)H(2n); \"alkenes\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual alkene species, e.g., ethene and propene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition.json index b66c1d679..9a3bf913a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission.json index 48597e948..8f5b12fea 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission.json index 234ea1bd2..f06f978dc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission", + "id": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Re-emission\" refers to emission that is not from a primary source; it refers to emission of a species that has previously been deposited and accumulated in soils or water. \"Re-emission\" is a process entirely distinct from \"emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition.json index f0fa2d49c..0f7ac4330 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission.json index 82b28c71d..98b7a4e81 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_alpha_pinene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json index 6bff949c5..64ce89fa7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission.json index 0ff6f4eac..79644d9ce 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production.json index 9812e116e..09f507d5c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning.json index 5abc59ed8..f3ab6c0e2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution.json index 480c01338..4e9ec9180 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires.json index 6b71d0da5..03d302406 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. he chemical formula for ammonia is NH3. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion.json index 9f0a37a8d..10cbe59d0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport.json index d3b73861a..4b5c7ff75 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion.json index abcb846f3..9813656bd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires.json index c7ee3e8dc..2ca735801 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ammonia is NH3. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json index e753283d4..e4774e225 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json index c8d8f2837..71f317ffd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for ammonium is NH4.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production.json index 6bd756363..ff5ca4e20 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production", + "id": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_net_chemical_production", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Net chemical production\" means the net result (calculated as production minus destruction) of all chemical reactions within the medium (here, atmosphere) that produce or destroy a particular species. The chemical formula for the ammonium cation is NH4+.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json index 253072630..a7a768dd1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for ammonium is NH4.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission.json index 95030d0bc..7e0a0ff6c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_aromatic_compounds_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. Aromatic compounds in organic chemistry are compounds that contain at least one benzene ring of six carbon atoms joined by alternating single and double covalent bonds. The simplest aromatic compound is benzene itself. In standard names \"aromatic_compounds\" is the term used to describe the group of aromatic chemical species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual aromatic species, e.g. benzene and xylene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission.json index 2697c6c6a..81bb99c21 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production.json index 0c02f1b65..3a19e9b91 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning.json index 334af307a..609813091 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution.json index 4cc18ac43..07eb615d3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires.json index e50857b56..66ffa57ca 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion.json index ec6b9846d..483eae63e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport.json index 9ed582155..e29182ad1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion.json index 57d24c177..2bea73f40 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires.json index e38bcafb6..d106b7f3a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal.json index 0f34cd657..73a45dddd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_benzene_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission.json index aca4ef208..56e1ae744 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_beta_pinene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission.json index a86b3a09c..78848716e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Biogenic\" means influenced, caused, or created by natural processes. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission.json index e2f8970f2..1bf393b8d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production.json index 3be00e2e3..2e237b58e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning.json index d49f0d865..9026da931 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution.json index f3620871a..952dbd891 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires.json index ef0e4936e..3a5e1d23c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion.json index 45d29efff..325e0dc96 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport.json index 7c562af2a..d37753be5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport.json index bb7098316..676b7398b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion.json index b8cdd4337..a903f59fb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires.json index deffa6ddf..83b626549 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal.json index 737ed51c4..6850dc2ed 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_butane_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission.json index 5389b7bda..b0a966c81 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission.json index 9bedc2bc2..81a8f5084 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission", + "id": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2. \"Anthropogenic\" means influenced, caused, or created by human activity. Anthropogenic emission of carbon dioxide includes fossil fuel use, cement production, agricultural burning and sources associated with anthropogenic land use change, except forest regrowth.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products.json index ee458b92a..f43d06913 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products", + "id": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products", "description": "\"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The chemical formula for carbon dioxide is CO2. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Examples of \"forestry and agricultural products\" are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion.json index 14a31f339..4566cf328 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion", + "id": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon dioxide is CO2. Fossil fuel combustion includes cement production and flaring of natural gas.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition.json index 3e6608c7a..be1cdf4d9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission.json index 2abddb0e2..1ec697abe 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production.json index bb461acce..f1d8b74c1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning.json index 6affeb2fe..5a91c44ee 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution.json index 247dbd5bf..4c1ee5a8e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_energy_production_and_distribution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires.json index 608315b36..089b2103e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion.json index 41b9d3e61..6e8940ad3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_industrial_processes_and_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport.json index 064c9c7c6..c03c98b5a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_land_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport.json index 6b30cb209..395f880bb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_maritime_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion.json index 30ae3a234..dc54cb972 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_residential_and_commercial_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon monoxide is CO. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires.json index 68bb9aebc..67debff29 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use.json index 74436b253..414a2462e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_solvent_production_and_use", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for carbon monoxide is CO. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal.json index cc4db42bd..d846f0095 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission_from_waste_treatment_and_disposal", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon monoxide is CO. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission.json index 4c9813487..bfa58fe81 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_carbon_tetrachloride_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission.json index cd95fd119..d0a06f561 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_cfc113_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission.json index dc7754395..0659bc6f2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_cfc113a_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission.json index 9e533599f..2a6bf4616 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_cfc114_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission.json index a48046553..317ac9e7b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_cfc115_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer are used\". The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission.json index 904323a5d..692058087 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_cfc11_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission.json index ff9a4207c..f79f57f5d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_cfc12_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires.json index 0f4ecdc64..22d4182f3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Chlorinated hydrocarbons are a group of chemicals composed of carbon, chlorine and hydrogen. As pesticides, they are also referred to by several other names, including chlorinated organics, chlorinated insecticides and chlorinated synthetics. In standard names \"chlorinated_hydrocarbons\" is the term used to describe the group of chlorinated hydrocarbon species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport.json index 9b56a5bba..352dae218 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Chlorinated hydrocarbons are a group of chemicals composed of carbon, chlorine and hydrogen. As pesticides, they are also referred to by several other names, including chlorinated organics, chlorinated insecticides and chlorinated synthetics. In standard names \"chlorinated_hydrocarbons\" is the term used to describe the group of chlorinated hydrocarbon species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires.json index fd33b0afe..8ec9d0b9c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Chlorinated hydrocarbons are a group of chemicals composed of carbon, chlorine and hydrogen. As pesticides, they are also referred to by several other names, including chlorinated organics, chlorinated insecticides and chlorinated synthetics. In standard names \"chlorinated_hydrocarbons\" is the term used to describe the group of chlorinated hydrocarbon species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use.json index ab79d8907..5bac967f5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Chlorinated hydrocarbons are a group of chemicals composed of carbon, chlorine and hydrogen. As pesticides, they are also referred to by several other names, including chlorinated organics, chlorinated insecticides and chlorinated synthetics. In standard names \"chlorinated_hydrocarbons\" is the term used to describe the group of chlorinated hydrocarbon species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal.json index bbf775737..d368852d7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_chlorinated_hydrocarbons_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Chlorinated hydrocarbons are a group of chemicals composed of carbon, chlorine and hydrogen. As pesticides, they are also referred to by several other names, including chlorinated organics, chlorinated insecticides and chlorinated synthetics. In standard names \"chlorinated_hydrocarbons\" is the term used to describe the group of chlorinated hydrocarbon species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition.json index f63f4ec40..5d63e5ca4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission.json index 7864c2ab5..73e4248ce 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires.json index 6e295eaa3..69f7b7ed3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires.json index c5286854e..4d325b3dd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition.json index 0f6db64a2..d149f6957 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json index 3d4fdacc0..fc4ab063d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", + "id": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json index 8ae250cfb..3f30610a2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission.json index 00b35ebda..9a7beabf9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling.json index c37fc0f19..f34e039d4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling", + "id": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_gravitational_settling", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition.json index 7a19a6b57..f8fdb9153 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition", + "id": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_turbulent_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json index 7a99b7373..88838f986 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json index cb3b37902..e0326603a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission.json index 5a5716365..1d53dddd3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning.json index 7de3b3fb5..b32ac5f43 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution.json index 474a9af1d..49377077a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires.json index 8ca29b27b..6a544254c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion.json index 401cfbc7e..67eb5fee1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport.json index fd492836c..b91402f8e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport.json index aaf6bb1dc..6c625cc42 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion.json index f73859a0b..653215b56 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The mass is the total mass of the particles. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires.json index 6a15dffa9..05bb1fa04 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal.json index 0cab94d39..740682f9b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling.json index 8385cda9d..34057a281 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_gravitational_settling", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. The sum of turbulent deposition and gravitational settling is dry deposition. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition.json index b354039c5..1af523af5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_turbulent_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json index 5974ec3a7..640da97a1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport.json index fd652a87d..23c3a57f2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Esters in organic chemistry are chemical compounds derived by reacting an oxoacid with a hydroxyl compound such as an alcohol or phenol. Esters are usually derived from an inorganic acid or organic acid in which at least one -OH (hydroxyl) group is replaced by an -O-alkyl (alkoxy) group, and most commonly from carboxylic acids and alcohols. That is, esters are formed by condensing an acid with an alcohol. In standard names \"esters\" is the term used to describe the group of ester species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use.json index 2e5759b20..8bf61d7d0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Esters in organic chemistry are chemical compounds derived by reacting an oxoacid with a hydroxyl compound such as an alcohol or phenol. Esters are usually derived from an inorganic acid or organic acid in which at least one -OH (hydroxyl) group is replaced by an -O-alkyl (alkoxy) group, and most commonly from carboxylic acids and alcohols. That is, esters are formed by condensing an acid with an alcohol. In standard names \"esters\" is the term used to describe the group of ester species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal.json index 00a546f67..77f4583a3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_esters_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Esters in organic chemistry are chemical compounds derived by reacting an oxoacid with a hydroxyl compound such as an alcohol or phenol. Esters are usually derived from an inorganic acid or organic acid in which at least one -OH (hydroxyl) group is replaced by an -O-alkyl (alkoxy) group, and most commonly from carboxylic acids and alcohols. That is, esters are formed by condensing an acid with an alcohol. In standard names \"esters\" is the term used to describe the group of ester species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission.json index bf3b9f540..8158f8ba8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production.json index a473c59c4..bc55765f5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning.json index b34613fba..bcbc1a138 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution.json index 71101edc5..2be906ddf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_energy_production_and_distribution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires.json index 825db56a5..8d8e1b850 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion.json index eb03c47eb..81381f8cd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_industrial_processes_and_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport.json index 1fee125c3..0d28b8c0d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_land_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport.json index 45d1cd068..4c3c67282 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_maritime_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion.json index 3070c476c..2bed5da16 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_residential_and_commercial_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires.json index a63b904d4..0ccfe2967 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal.json index 7c3176814..da2d4a17b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethane_due_to_emission_from_waste_treatment_and_disposal", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission.json index ce3bcdde3..45c34e57a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethanol_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission.json index af486b2ec..ffc4c3f55 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production.json index c4d840315..b08e1b9a6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning.json index 6b979b9e6..03d39deb2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution.json index 7ed830cdf..aad2f657b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_energy_production_and_distribution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires.json index c81d404fc..74e455757 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion.json index f8ff5741a..5ebadcc0e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_industrial_processes_and_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport.json index bafbb6a11..a3cd22ec5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_land_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport.json index 84280931c..bbc528ae8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_maritime_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion.json index ee1e28832..23b677663 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_residential_and_commercial_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires.json index 48c23164d..d69460bd5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal.json index 71d3a7440..7a75d29b4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethene_due_to_emission_from_waste_treatment_and_disposal", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production.json index 55da4f0b6..d6be2c206 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires.json index d14c1c3cf..5170fe851 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport.json index c09f32dfb..93221ccf3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion.json index 88b564827..cd4b746da 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires.json index b3122f2c3..d90bd7b2c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use.json index ee6e8b95e..09e663c51 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal.json index 8c8a2ee1b..d84e0cb8e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethers_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Ethers are a class of organic compounds that contain an ether group - an oxygen atom connected to two alkyl or aryl groups - of general formula R-O-R. In standard names \"ethers\" is the term used to describe the group of ether species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission.json index 8a6bed7bf..f725b6fd6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production.json index 821aee080..1404099aa 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning.json index 1e9163619..d2f53ced8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution.json index 0cac673c3..cc7be7ccd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_energy_production_and_distribution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires.json index f99d453bb..6682cdeef 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion.json index 08b29e84b..d148cdbb3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_industrial_processes_and_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport.json index a490edf44..1d6a3fc1b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_land_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport.json index 5952cd72d..58a71b61d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_maritime_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion.json index 161c30532..4e6f2f457 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_residential_and_commercial_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires.json index 2a46dee49..55597353c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal.json index 79d363f2b..acd3d33f8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ethyne_due_to_emission_from_waste_treatment_and_disposal", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition.json index cc7d2255d..2abff9796 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission.json index 3a570ecae..9175c0aff 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production.json index b4df89b81..bff5a9a8b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning.json index 13abd346a..31a536319 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution.json index cc03765cf..38f041ec6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_energy_production_and_distribution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires.json index 8807bf206..65c682843 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion.json index b46e4b42e..36931a424 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_industrial_processes_and_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport.json index bf00a4fa3..1f99af353 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_land_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion.json index 7f2ac7660..527240875 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_residential_and_commercial_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires.json index f5115e6e1..f2ddf67bf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal.json index 5c356c6a3..b394fe662 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_emission_from_waste_treatment_and_disposal", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition.json index eb112716f..11b576c47 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formaldehyde_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition.json index 03d468e80..c69be82d5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formic_acid_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition.json index 729c4b6bf..1d1f22008 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_formic_acid_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition.json index a53089192..83dd99606 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission.json index 30f2c0e49..22592bf24 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition.json index 18692f3e1..15c706ad3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition.json index a55d3a0b4..726e4293c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission.json index c7fa7404b..b630c9ef8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition.json index 9f543f439..d127fea6b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission.json index 7ded1edc6..689a97ab2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_halon1202_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission.json index 9fae5b731..79140406b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_halon1211_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission.json index 9c3744188..4b3190ad6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_halon1301_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission.json index a832ed5b8..1919e2ec5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_halon2402_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission.json index 9b32a79eb..6dd66b1dc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hcc140a_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission.json index df346370c..c5e228791 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hcfc141b_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission.json index 464760805..3679b22c5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hcfc142b_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission.json index 6f80c0591..96c9024c9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hcfc22_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition.json index 2e1bdff73..3df32971d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for hexachlorobiphenyl is C12H4Cl6. The structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission.json index 13dc8a7ce..227811b58 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for hexachlorobiphenyl is C12H4Cl6. The structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission.json index 0a6a477c7..a132c3f18 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission", + "id": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Re-emission\" refers to emission that is not from a primary source; it refers to emission of a species that has previously been deposited and accumulated in soils or water. \"Re-emission\" is a process entirely distinct from \"emission\" which is used in some standard names. The chemical formula for hexachlorobiphenyl is C12H4Cl6. The structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition.json index 4d64820b8..4cea6c7f3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. The chemical formula for hexachlorobiphenyl is C12H4Cl6. The structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition.json index 739d76142..8ad916521 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission.json index 6b891bb1a..48cd33007 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hydrogen_cyanide_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition.json index 4d7ec7ab9..72cb6e2ce 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_dry_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition.json index f3f37ceb5..b0669efc2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_hydrogen_peroxide_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json index d3ae99c79..6e5a5aac1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", + "id": "tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Insoluble aerosol\" means aerosol which is not soluble in water, such as mineral dusts. At low temperatures such particles can be efficient nuclei for ice clouds. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission.json index eb7315569..c453f3926 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires.json index bb43b643e..1d92da2ee 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires.json index 5ac0989ad..67a3601e0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production.json index 057ef79c0..22a905f34 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning.json index f493ad4f2..d4219a48e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution.json index 9382bbb2f..aa8dc9484 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires.json index 032a8b7f8..dce98d0a1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion.json index 6767ec682..6ee72f083 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport.json index 5a93de780..a61948a43 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion.json index dc95548dd..a63f129e5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires.json index 8d2b2b68f..1fcbd928c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use.json index 4f662e769..31dd6fce7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal.json index 3b94c8799..36e333d0e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ketones_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. In organic chemistry, a ketone is a compound with the structure RC(=O)R', where R and R' can be a variety of atoms and groups of atoms. It features a carbonyl group (C=O) bonded to two other carbon atoms. Acetone is the simplest example of a ketone. In standard names \"ketones\" is the term used to describe the group of ketone species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_limonene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_limonene_due_to_emission.json index 4834af591..0d4ec3040 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_limonene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_limonene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_limonene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_limonene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_limonene_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition.json index 32710a6ff..36e169b6e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission.json index 3f43e40d8..36bf55cd2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition.json index f0b4b45da..93f7a416f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission.json index 66f95e6d7..ce603fc71 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production.json index aca45c55f..0a6c51730 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning.json index b39f240cd..07303c1c6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution.json index 01a49beab..1cf1d253d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires.json index 3593019c4..b18e4924d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion.json index 8cee342b9..52242b8c6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport.json index 16db1ff2e..25549e69d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. he chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport.json index 1633daa41..1a57ec165 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion.json index 08cb27344..899a6185c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires.json index 8dbcf4b57..a7ef948ce 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal.json index 1ee20c10b..475815daf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methane_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production.json index 6eacb6617..029e5cc00 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production", + "id": "tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_net_chemical_production", "description": "Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Net chemical production\" means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for methanesulfonic acid is CH3SO3H.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition.json index 8f716b374..73772633b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for methanesulfonic acid is CH3SO3H.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition.json index eb928714d..6b461fca1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methanesulfonic_acid_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for methanesulfonic acid is CH3SO3H.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanol_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanol_due_to_emission.json index fcdaf446e..6f810c2e4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanol_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methanol_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methanol_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_methanol_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methanol_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission.json index 4ece2f724..904a009a3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methyl_bromide_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission.json index 5702108f1..b79c5b614 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_methyl_chloride_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition.json index 9ef4ef8a0..c9e57784c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission.json index 0a0afdf92..bf076b18f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires.json index d63effa92..a620e902a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for molecular hydrogen is H2. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires.json index 339c36ab1..e8d5ee4b7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_molecular_hydrogen_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for molecular hydrogen is H2. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission.json index 6ddba06a1..6a7ed3102 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_monoterpenes_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. Monoterpenes are a class of terpenes that consist of two isoprene units and have the molecular formula C10H16. Terpenes are hydrocarbons. The term \"monoterpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition.json index 7870c9772..f737d1018 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production.json index 413b24dc1..64263ccea 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production", + "id": "tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_net_chemical_production", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Net chemical production\" means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition.json index 05e7993dd..a84c972da 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrate_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition.json index db79ddf5a..d5dd1a61d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition", "description": "quot;Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition.json index f51b69f71..702b8c29f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission.json index 0a069adcb..04018289b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change.json index 3cfbd1158..20202e59f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_land_use_or_land_cover_change", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Anthropogenic\" means influenced, caused, or created by human activity. \"Anthropogenic land use change\" means human changes to land, excluding forest regrowth. It includes fires ignited by humans for the purpose of land use change and the processes of eventual disposal and decomposition of wood products such as paper, cardboard, furniture and timber for construction.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json index c07f418ea..0e2d87678 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. Usually, particle bound and gaseous nitrogen compounds, such as atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), ammonia (NH3), ammonium (NH4+), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)) are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json index ded4a99af..895e7f664 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"dry_deposition\" is the sum of turbulent deposition and gravitational settling. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. Usually, particle bound and gaseous nitrogen compounds, such as atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), ammonia (NH3), ammonium (NH4+), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)) are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json index 59fb541f7..074246110 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. Usually, particle bound and gaseous nitrogen compounds, such as atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), ammonia (NH3), ammonium (NH4+), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)) are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition.json index 44a420c70..f9f5b144d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission.json index a69b6aa3a..1384ace4f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires.json index aeb072c2b..bd411d224 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen dioxide is NO2. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires.json index a91f5f925..06d1af350 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen dioxide is NO2. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission.json index af1b91835..709048554 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production.json index b74fc0295..5f14c7a8d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json index a14255d27..621775206 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json index 6a47572e8..29cf92848 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires.json index 5da935c7e..e602fe3f1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json index fd0bf1620..c94d9e8e6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport.json index e2193518f..d289459de 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport.json index 319f3f4dc..886eafc15 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json index 547bf191c..c2f8f2d9e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json index 1a735a007..c0bde699f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json index 7d0396df0..415d8d885 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition.json index f43e27852..8cff4c77c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission.json index 07ff2f415..9b3ee47a3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition.json index 9727b2702..a9c6cd302 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrous_acid_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition.json index d2764cde5..788b9df61 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission.json index 55953efaa..143f35b74 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nitrous_oxide_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission.json index d52065448..0a68d4576 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production.json index 30e8311d2..2b41f57b6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning.json index 3c16245c0..f464d2f10 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution.json index eefa401fa..bb5bb0ac5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires.json index d9b685e5b..a88ed28c1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion.json index fbb4e9267..f9fe40ac1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport.json index 02860819c..965a35318 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport.json index f08281dae..0b7125218 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion.json index 55f8eebd1..ee69b45d8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires.json index d13814da6..c7682c524 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use.json index 7c719d97f..3030e7d3b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal.json index 8a321db09..71bfaca10 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission.json index a4c91f49d..9b6cb6d68 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nmvoc_expressed_as_carbon_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. \"nmvoc\" means non methane volatile organic compounds. \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission.json index c488463f4..9f4b90f18 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Nox\" means nitric oxide (NO) and nitrogen dioxide (NO2). \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production.json index df8026b8f..aa5a81a58 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json index 31b4b1e63..d95b00007 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json index 6cfd38180..9713d0f81 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires.json index 1388c8f92..76f284161 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json index 4577809a5..3712d258c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport.json index db80de1d2..2d972a546 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport.json index f9ddc29d4..272bc2301 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json index 289fe9c1e..d19fbd700 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json index 975599fc0..45e745262 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil.json index efc0f7d5b..2c696a83e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_soil", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for nitrogen monoxide is NO. \"Nox\" means a combination of two radical species containing nitrogen and oxygen NO+NO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json index 8347efd20..d5707cdf3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_monoxide_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json index 506e9360d..d5c6708b8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json index ce8fe8c86..7913922f6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production.json index 3df4d4166..6339be946 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning.json index 1878711e4..1dd8f9cb5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution.json index 509f7f7e0..59fb840a4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires.json index 316db3ff6..4f42aab3c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion.json index de20459bb..248beb8e1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion.json index 6929f43b3..f5ad08a6b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires.json index c3e891123..0dfe02329 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal.json index 2477f8f37..984fe9a8a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_acids_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. An organic acid is an organic compound with acidic properties. The most common organic acids are the carboxylic acids, whose acidity is associated with their carboxyl group -COOH. In standard names \"organic_acids\" is the term used to describe the group of organic acid species that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition.json index 5b80a2d28..2f4048692 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. Organic nitrates are nitrogen-containing compounds having the general formula RONO2, where R is an alkyl (or organic) group; \"organic nitrates\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition.json index 63fc5cc09..e33970858 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_nitrates_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. Organic nitrates are nitrogen-containing compounds having the general formula RONO2, where R is an alkyl (or organic) group; \"organic_nitrates\" is the term used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition.json index 9d4552940..27e746423 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. Organic peroxides are organic molecules containing an oxygen-oxygen bond. The general chemical formula is ROOR or ROOH, where R is an organic group.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition.json index 47cd93533..981a91b86 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_organic_peroxides_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. Organic peroxides are organic molecules containing an oxygen-oxygen bond. The general chemical formula is ROOR or ROOH, where R is an organic group.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json index f8b8ee780..a1245c64a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", + "id": "tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "description": "\"Content\" indicates a quantity per unit area. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition. \"Oxidized nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state greater than zero. Usually, particle bound and gaseous nitrogen compounds, such as nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json index e443e2add..6c1867a69 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"Oxidized nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state greater than zero. Usually, particle bound and gaseous nitrogen compounds, such as nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json index ac1e40955..17716f85e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"Oxidized nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state greater than zero. Usually, particle bound and gaseous nitrogen compounds, such as nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json index 7a75f9547..01644d367 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata.json index d459bd969..a42e11a5c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata", + "id": "tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\"is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json index 0073abed1..7fa34c50b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json index 0f0cb4b1b..440b810cd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except black carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling.json index 67efa2547..c68d61228 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_gravitational_settling", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission.json index 378f41246..be6b2849e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Net chemical production\" means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species. \"tendency_of_X\" means derivative of X with respect to time. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition.json index 9d825dcb2..e79d99532 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_turbulent_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json index d1dd0d5e9..b07fc660f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition.json index 9207dc7d9..1fcb4b4ee 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except black carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission.json index 5b32f2b16..b71945184 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except black carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning.json index f51a538d9..e828f4478 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution.json index 0811e89bc..865f87ccf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires.json index 90e053132..cecc274ab 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion.json index 9847dd6fc..df6249ad2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport.json index beebe2465..f3127ce50 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport.json index f61275e9e..40d14a6fd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion.json index d4bb02441..bf13a5c0e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires.json index 1b8c3b777..6b4484fa0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Primary particulate organic matter \" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal.json index 1d7cb08b6..fd0bb4a10 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, waste water handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition.json index c194a834d..85f464047 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_expressed_as_carbon_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The term \"particulate_organic_matter_dry_aerosol\" means all particulate organic matter dry aerosol except elemental carbon. It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production.json index 76a5ed8b6..ecc6b2530 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning.json index 61cb3ba31..34f63d249 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires.json index 985f614d5..85e1fe458 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion.json index 5c1e7562b..97bbe126e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport.json index fc5f8ca3c..149e41922 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport.json index ffcbe09cd..cf94d5836 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion.json index 1ae486375..06a74a483 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires.json index 8c13e1967..93ddb8ad6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for pentane is C5H12. Pentane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal.json index ab92a3d71..66954e76b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pentane_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition.json index 02bcc09ea..6ff89be5e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_peroxyacetyl_nitrate_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl_nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition.json index dd57db639..1c089a956 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_peroxynitric_acid_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition.json index 0baff510d..d7e434a03 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission.json index 6021430d4..a7b41585c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition.json index 8d09322e7..a74dfd1e0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition.json index ff3076c69..4c9220d54 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission.json index 97d82dad7..b9380ca8d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition.json index df0a79ef7..f891015cb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_dust_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json index 2fa1d5841..9cfe7a4f3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission.json index e59f61414..7ffcab55a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json index 7c94422cc..f4bc8fa86 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm10_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm10 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition.json index 366f0eec9..dee7f1c60 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission.json index c761e5862..364f0a159 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition.json index 2e94a4d6e..4286cc160 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition.json index 7258985eb..e05a96981 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission.json index 103a92ff8..bb8f05ce7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition.json index 69c96c033..aba66a80e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_dust_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json index 600a944b8..3bfb13f59 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission.json index 895b0a768..251b28463 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json index 60f0bb5bc..0c4490eb8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_pm2p5_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Pm2p5 aerosol\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json index 15b88ffc5..6e65f4652 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json index c3bf0f911..c10cb9781 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol.\"Dry aerosol particles\" means aerosol particles without any water uptake. \"Primary particulate organic matter \" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json index 0204e88c0..af03466f5 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Primary particulate organic matter \" means all organic matter emitted directly to the atmosphere as particles except elemental carbon. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission.json index 73c0212af..a9dbdea85 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production.json index bda800625..636d74a43 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning.json index 43033a843..52a1035cd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution.json index ee2f3eec1..be462c8c8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires.json index 333ddf36d..9dbb9c426 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion.json index 7bb834b81..fcb484075 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport.json index 1cc73dbc1..6d97d3ef1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport.json index 0451bb545..44e8eceba 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion.json index 47cac1798..27ea9c1c4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires.json index 5376e5b2b..f5e2a2c43 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal.json index 585d9cd14..0a3adba74 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propane_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission.json index b1bbcf7d2..cdbdfc314 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production.json index 88ccfcf5e..2755065bf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning.json index e440b14d8..f23ec93c4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution.json index 127f51af2..87f5838cb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires.json index e7ffabe29..b6501f62c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion.json index 0eb6952c6..08bae83dc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport.json index f4aa004ca..0d3be5b90 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport.json index 9e4a60b7f..ec8f19f49 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion.json index 36455f733..bca09bd4d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires.json index 329649436..403d06603 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal.json index dbe5cd1fd..923abbddc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_propene_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_radon_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_radon_due_to_emission.json index c6f1a7852..afb134cea 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_radon_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_radon_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_radon_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_radon_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_radon_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json index 6a210a503..298f22fc0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", + "id": "tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Deposition\" is the sum of wet and dry deposition. \"Reduced nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state less than zero. Usually, particle bound and gaseous nitrogen compounds, primarily ammonium (NH4+) and ammonia (NH3), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json index 05346f91b..b142a29df 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"Reduced nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state less than zero. Usually, particle bound and gaseous nitrogen compounds, primarily ammonium (NH4+) and ammonia (NH3), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json index 96fd1e814..8aa7ca964 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"Reduced nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state less than zero. Usually, particle bound and gaseous nitrogen compounds, primarily ammonium (NH4+) and ammonia (NH3), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json index 557e80ec8..10cfaadc8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission.json index 485e94972..f33709b3e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling.json index 71bf663b7..db2dd69ef 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling", + "id": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_gravitational_settling", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition.json index c307fdb02..7c39f0919 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_turbulent_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json index e9480d64d..1f4ec35c2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json index 9988028b3..4ba3e7dc1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json index 2179716cd..44b0301b1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Secondary particulate organic matter\" means particulate organic matter formed within the atmosphere from gaseous precursors. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production.json index 91b2e3305..1a99a7b78 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production", + "id": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Secondary particulate organic matter\" means particulate organic matter formed within the atmosphere from gaseous precursors. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Net chemical production\" means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json index c1003a51e..910cbe66d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"Secondary particulate organic matter\" means particulate organic matter formed within the atmosphere from gaseous precursors. The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission.json index 63ee4b158..d0f4a5bcc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sesquiterpenes_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. Terpenes are hydrocarbons, that is, they contain only hydrogen and carbon combined in the general proportions (C5H8)n where n is an integer greater than on equal to one. Sesquiterpenes are a class of terpenes that consist of three isoprene units and have the molecular formula C15H24. Terpenes are hydrocarbons. The term \"sesquiterpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production.json index 098948637..a8a8f9dc8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Net chemical production\" means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species. \"Aqueous phase net chemical production\" means the net result of all aqueous chemical processes in fog and clouds that produce or destroy a species, as opposed to chemical processes in the gaseous phase. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json index 3dd0ff870..e4d5cb3f0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission.json index efd9f937b..53cd7cb12 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production.json index 5bdd2c8e6..45e1ecb5f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Gaseous phase net chemical production\" means the net result of all gaseous chemical processes in the atmosphere that produce or destroy a species, distinct from chemical processes in the aqueous phase. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json index e726f2966..da4ad1f9f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the particles. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition.json index 52c9c3a20..b5afb19f0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling.json index d5fd436cc..09bac921a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_gravitational_settling", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition.json index 315e214f3..162d757aa 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_turbulent_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition.json index a6b4718de..22894caf4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_expressed_as_sulfur_due_to_wet_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer are used\". \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json index f503e5e2a..5d5e4de35 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission.json index 6b09a8898..b84dad5d1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning.json index 9a7615943..cdb4e9d9f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution.json index f41c7d173..326c5fcf9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires.json index 1918936f0..dc06ff9f6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion.json index 01c0bcd12..611c16a09 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport.json index b9314eb7d..3bf63f6e4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport.json index 4e70e730a..f14c07bb6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion.json index 705614f64..ac0b5768a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires.json index 21bd7cebe..33f39063c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal.json index c5ed26d55..4d6a116f0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for sulfur dioxide is SO2. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json index 80f6772b8..b45b3539b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", + "id": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Wet deposition\" means deposition by precipitation.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires.json index 8b239e911..24e9aaec0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Terpenes are hydrocarbons, that is, they contain only hydrogen and carbon combined in the general proportions (C5H8)n where n is an integer greater than on equal to one. The term \"terpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual terpene species, e.g., isoprene and limonene. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires.json index cd6bd3e11..9fd2a1377 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_terpenes_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. Terpenes are hydrocarbons, that is, they contain only hydrogen and carbon combined in the general proportions (C5H8)n where n is an integer greater than on equal to one. The term \"terpenes\" is used in standard names to describe the group of chemical species having this common structure that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names exist for some individual terpene species, e.g., isoprene and limonene. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission.json index 163d8e5e0..6fb7a8cf1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production.json index d1685e050..ff891bcf6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning.json index 454987e19..79cf4a476 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_agricultural_waste_burning", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution.json index d8d7aff42..4512e63e3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_energy_production_and_distribution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires.json index 9f0f78ab3..11b3172b2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_forest_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion.json index 7fdda7305..826d6fe5a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_industrial_processes_and_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport.json index 5e3fb7c14..fbb16bbb9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_land_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport.json index a9e842506..3673cc3da 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_maritime_transport", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion.json index 4d5834661..05dcc7dc9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_residential_and_commercial_combustion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires.json index 86d98b323..5380c4939 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_savanna_and_grassland_fires", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use.json index 7bbd9f03b..15117f03c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_solvent_production_and_use", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal.json index e1c1e317d..f0bf04327 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_toluene_due_to_emission_from_waste_treatment_and_disposal", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution.json index 2f0f97f94..fec0236dd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_trimethylbenzene_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for trimethylbenzene is C9H12. The IUPAC names for trimethylbenzene is 1,3,5-trimethylbenzene. Trimethylbenzene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_due_to_advection.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_due_to_advection.json index af73d33e1..5f21a834d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_due_to_advection", + "id": "tendency_of_atmosphere_mass_content_of_water_due_to_advection", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor.json index 3063ddc94..1df7b2cb0 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection.json index 6401d6c97..ad02a1623 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection.json index e2b918e1b..a1367fd33 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection.json index 321aa4c25..4db40af6b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_deep_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection.json index 00e4cfbdc..a00268e9e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_shallow_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice.json index 744dee9eb..caa0d3971 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sublimation is the conversion of solid into vapor. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow.json index 2085ad73a..769874196 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sublimation is the conversion of solid into vapor. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice.json index 4acd1045f..f62da6f0c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sublimation is the conversion of solid into vapor. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence.json index 8a38f25cc..c163847ce 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence", + "id": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_turbulence", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as \"precipitable water\", although this term does not imply the water could all be precipitated.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission.json index 7fafdfb32..8ce530728 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production.json index 50ce9d168..802cf7180 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"agricultural production\" sector comprises the agricultural processes of enteric fermentation, manure management, rice cultivation, agricultural soils and other. It may also include any not-classified or \"other\" combustion, which is commonly included in agriculture-related inventory data. \"Agricultural production\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 4A, 4B, 4C, 4D and 4G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning.json index e46e5d581..5e8e89e3b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_agricultural_waste_burning", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"agricultural waste burning\" sector comprises field burning of agricultural residues. \"Agricultural waste burning\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 4F as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution.json index bc8e55924..efa1a3666 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_energy_production_and_distribution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"energy production and distribution\" sector comprises fuel combustion activities related to energy industries and fugitive emissions from fuels. It may also include any not-classified or \"other\" combustion, which is commonly included in energy-related inventory data. \"Energy production and distribution\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A1 and 1B as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires.json index 90d684572..4fecc968f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_forest_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"forest fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in forests. \"Forest fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion.json index 563dc2acd..be50bb180 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_industrial_processes_and_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"industrial processes and combustion\" sector comprises fuel combustion activities related to manufacturing industries and construction, industrial processes related to mineral products, the chemical industry, metal production, the production of pulp, paper, food and drink, and non-energy industry use of lubricants and waxes. It may also include any not-classified or \"other\" combustion, which is commonly included in industry-related inventory data. \"Industrial processes and combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A2, 2A, 2B, 2C, 2D and 2G as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport.json index f9b3c845f..f92aaed9a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_land_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"land transport\" sector includes fuel combustion activities related to road transportation, railways and other transportation. \"Land transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A3b, 1A3c and 1A3e as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport.json index c12d8b26b..364e4f7df 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_maritime_transport", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"maritime transport\" sector includes fuel combustion activities related to maritime transport. \"Maritime transport\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3d as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion.json index 28506ac27..b84d903de 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_residential_and_commercial_combustion", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"residential and commercial combustion\" sector comprises fuel combustion activities related to the commercial/institutional sector, the residential sector and the agriculture/forestry/fishing sector. It may also include any not-classified or \"other\" combustion, which is commonly included in the inventory data. \"Residential and commercial combustion\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 1A4a, 1A4b and 1A4c as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires.json index 37e66810a..1c15561dc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_savanna_and_grassland_fires", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"savanna and grassland fires\" sector comprises the burning (natural and human-induced) of living or dead vegetation in non-forested areas. It excludes field burning of agricultural residues. \"Savanna and grassland fires\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 5 as defined in the 2006 IPCC guidelines for national greenhouse gas Inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use.json index aae4a90d7..30d955490 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_solvent_production_and_use", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"solvent production and use\" sector comprises industrial processes related to the consumption of halocarbons, SF6, solvent and other product use. \"Solvent production and use\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 2F and 3 as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal.json index c2ec23401..d084db92c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal", + "id": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal", "type": "standard_name", "name": "tendency_of_atmosphere_mass_content_of_xylene_due_to_emission_from_waste_treatment_and_disposal", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species. The \"waste treatment and disposal\" sector comprises solid waste disposal on land, wastewater handling, waste incineration and other waste disposal. \"Waste treatment and disposal\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source categories 6A, 6B, 6C and 6D as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area.json index 8b057ef62..e9fff9737 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_per_unit_area", + "id": "tendency_of_atmosphere_mass_per_unit_area", "type": "standard_name", "name": "tendency_of_atmosphere_mass_per_unit_area", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"X_area\" means the horizontal area occupied by X within the grid cell.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area_due_to_advection.json b/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area_due_to_advection.json index 6a2f8eefa..f280c4bcf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mass_per_unit_area_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mass_per_unit_area_due_to_advection", + "id": "tendency_of_atmosphere_mass_per_unit_area_due_to_advection", "type": "standard_name", "name": "tendency_of_atmosphere_mass_per_unit_area_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"X_area\" means the horizontal area occupied by X within the grid cell.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction.json index 980d31eab..9b72307c6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction", + "id": "tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical destruction\" means the result of all chemical reactions within the medium (here, atmosphere) that remove a certain amount of a particular species from the medium. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor.json index d2b20bfcf..aebd20db3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor", + "id": "tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_hydroxyl_radical_due_to_chemical_production_from_atomic_singlet_oxygen_and_water_vapor", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical production\" means the result of all chemical reactions within the medium (here, atmosphere) that produce a certain amount of the particular species. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species. The chemical formula for the hydroxyl radical is OH. The chemical formula for atomic_singlet_oxygen is O1D. The chemical formula for water vapor is H2O. Here, the production of hydroxyl radical is equal to 2k[O1D][H2O], i.e., 2 hydroxyl radicals are formed from the reaction of O1D with H2O. For models that do not have O1D as a species, the production of hydroxyl radical may be represented differently but the chemical production should take account of the hydroxyl yield.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction.json index f26191b5f..c96cd669e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction", + "id": "tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical destruction\" means the result of all chemical reactions within the medium (here, atmosphere) that remove a certain amount of a particular species from the medium. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction.json index 43337e812..003925157 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction", + "id": "tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The chemical formula for nitrous oxide is N2O. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical destruction\" means the result of all chemical reactions within the medium (here, atmosphere) that remove a certain amount of a particular species from the medium.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction.json index 8e6459f2f..5c0aa967a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction", + "id": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical destruction\" means the result of all chemical reactions within the medium (here, atmosphere) that remove a certain amount of a particular species from the medium. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production.json index 4b2eda5e1..3157498e2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production", + "id": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical production\" means the result of all chemical reactions within the medium (here, atmosphere) that produce a certain amount of the particular species. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production.json b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production.json index 9f8907500..53695b010 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production", + "id": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production", "type": "standard_name", "name": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_net_chemical_production", "description": "\"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Net chemical production\" means the net result (calculated as production minus destruction) of all chemical reactions within the medium (here, atmosphere) that produce or destroy a particular species. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_acetic_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_acetic_acid.json index 2c1f90605..5ad92285d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_acetic_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_acetic_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_acetic_acid", + "id": "tendency_of_atmosphere_moles_of_acetic_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_acetic_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for acetic_acid is CH3COOH. The IUPAC name for acetic acid is ethanoic acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_aceto_nitrile.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_aceto_nitrile.json index 631d00e60..fca6ddedb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_aceto_nitrile.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_aceto_nitrile.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_aceto_nitrile", + "id": "tendency_of_atmosphere_moles_of_aceto_nitrile", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_aceto_nitrile", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for aceto-nitrile is CH3CN. The IUPAC name for aceto-nitrile is ethanenitrile.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane.json index 1c39191e9..a3abeefdd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane", + "id": "tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_alpha_hexachlorocyclohexane", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for alpha_hexachlorocyclohexane is C6H6Cl6.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_pinene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_pinene.json index 9a25c74b3..18b3dbb4f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_pinene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_alpha_pinene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_alpha_pinene", + "id": "tendency_of_atmosphere_moles_of_alpha_pinene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_alpha_pinene", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for alpha_pinene is C10H16. The IUPAC name for alpha-pinene is (1S,5S)-2,6,6-trimethylbicyclo[3.1.1]hept-2-ene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ammonia.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ammonia.json index e35b63cce..52e1afa70 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ammonia.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ammonia.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_ammonia", + "id": "tendency_of_atmosphere_moles_of_ammonia", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_ammonia", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ammonia is NH3.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json index 55a0053c1..50f25f0fd 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon", + "id": "tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_anthropogenic_nmvoc_expressed_as_carbon", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Anthropogenic\" means influenced, caused, or created by human activity.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_bromine.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_bromine.json index c56fedbb1..403aa78a6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_bromine.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_atomic_bromine", + "id": "tendency_of_atmosphere_moles_of_atomic_bromine", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_atomic_bromine", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for atomic bromine is Br.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_chlorine.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_chlorine.json index 5422fd1b7..bed839bfe 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_chlorine.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_atomic_chlorine", + "id": "tendency_of_atmosphere_moles_of_atomic_chlorine", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_atomic_chlorine", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for atomic chlorine is Cl.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_nitrogen.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_nitrogen.json index f26ee1d78..a835a4bcc 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_nitrogen.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_atomic_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_atomic_nitrogen", + "id": "tendency_of_atmosphere_moles_of_atomic_nitrogen", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_atomic_nitrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for atomic nitrogen is N.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_benzene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_benzene.json index 980e980c2..0e26f91f1 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_benzene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_benzene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_benzene", + "id": "tendency_of_atmosphere_moles_of_benzene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_benzene", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for benzene is C6H6. Benzene is the simplest aromatic hydrocarbon and has a ring structure consisting of six carbon atoms joined by alternating single and double chemical bonds. Each carbon atom is additionally bonded to one hydrogen atom. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_beta_pinene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_beta_pinene.json index ab3b41a30..9de25f062 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_beta_pinene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_beta_pinene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_beta_pinene", + "id": "tendency_of_atmosphere_moles_of_beta_pinene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_beta_pinene", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for beta_pinene is C10H16. The IUPAC name for beta-pinene is (1S,5S)-6,6-dimethyl-2-methylenebicyclo[3.1.1]heptane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json index dab8bbe34..ceea23a8e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon", + "id": "tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_biogenic_nmvoc_expressed_as_carbon", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Biogenic\" means influenced, caused, or created by natural processes.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_chloride.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_chloride.json index dcab48620..7f243ee12 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_chloride.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_bromine_chloride", + "id": "tendency_of_atmosphere_moles_of_bromine_chloride", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_bromine_chloride", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for bromine chloride is BrCl.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_monoxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_monoxide.json index 5075201b2..0dbf4a54c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_monoxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_bromine_monoxide", + "id": "tendency_of_atmosphere_moles_of_bromine_monoxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_bromine_monoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for bromine monoxide is BrO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_nitrate.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_nitrate.json index d3fd93e1f..1b2b72ebe 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_nitrate.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_bromine_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_bromine_nitrate", + "id": "tendency_of_atmosphere_moles_of_bromine_nitrate", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_bromine_nitrate", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for bromine nitrate is BrONO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_brox_expressed_as_bromine.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_brox_expressed_as_bromine.json index 299121bcb..06aec5150 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_brox_expressed_as_bromine.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_brox_expressed_as_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_brox_expressed_as_bromine", + "id": "tendency_of_atmosphere_moles_of_brox_expressed_as_bromine", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_brox_expressed_as_bromine", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Brox\" describes a family of chemical species consisting of inorganic bromine compounds with the exception of hydrogen bromide (HBr) and bromine nitrate (BrONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Brox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. Standard names that use the term \"inorganic_bromine\" are used for quantities that contain all inorganic bromine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_butane.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_butane.json index e832f9b41..bb2bbb489 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_butane.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_butane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_butane", + "id": "tendency_of_atmosphere_moles_of_butane", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_butane", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for butane is C4H10. Butane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_dioxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_dioxide.json index a6d056aaf..e510defc2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_dioxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_carbon_dioxide", + "id": "tendency_of_atmosphere_moles_of_carbon_dioxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_carbon_dioxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for carbon dioxide is CO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_monoxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_monoxide.json index bead96249..818c0ac58 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_monoxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_carbon_monoxide", + "id": "tendency_of_atmosphere_moles_of_carbon_monoxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_carbon_monoxide", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_tetrachloride.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_tetrachloride.json index c6a349165..5a3fc898e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_tetrachloride.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_carbon_tetrachloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_carbon_tetrachloride", + "id": "tendency_of_atmosphere_moles_of_carbon_tetrachloride", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_carbon_tetrachloride", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of carbon tetrachloride is CCl4. The IUPAC name for carbon tetrachloride is tetrachloromethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc11.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc11.json index 3e70b951e..e090ba3c8 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc11.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc11.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_cfc11", + "id": "tendency_of_atmosphere_moles_of_cfc11", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_cfc11", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro(fluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113.json index 2b5aab09a..fd94e641b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_cfc113", + "id": "tendency_of_atmosphere_moles_of_cfc113", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_cfc113", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113a.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113a.json index 122f0294c..28be6cd5d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113a.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc113a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_cfc113a", + "id": "tendency_of_atmosphere_moles_of_cfc113a", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_cfc113a", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC113a is CCl3CF3. The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc114.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc114.json index 7f8e8adbb..36e3b4cfb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc114.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc114.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_cfc114", + "id": "tendency_of_atmosphere_moles_of_cfc114", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_cfc114", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC114 is CClF2CClF2. The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc115.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc115.json index 97463f37a..b42188f75 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc115.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc115.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_cfc115", + "id": "tendency_of_atmosphere_moles_of_cfc115", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_cfc115", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula of CFC115 is CClF2CF3. The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc12.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc12.json index 3acd124ea..a9a2bd20e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc12.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_cfc12.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_cfc12", + "id": "tendency_of_atmosphere_moles_of_cfc12", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_cfc12", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_dioxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_dioxide.json index 4a747de32..9fece7612 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_dioxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_chlorine_dioxide", + "id": "tendency_of_atmosphere_moles_of_chlorine_dioxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_chlorine_dioxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for chlorine dioxide is OClO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_monoxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_monoxide.json index bc5e0f00b..7bad7f430 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_monoxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_chlorine_monoxide", + "id": "tendency_of_atmosphere_moles_of_chlorine_monoxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_chlorine_monoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for chlorine monoxide is ClO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_nitrate.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_nitrate.json index 9fd6c606d..53677e3c3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_nitrate.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_chlorine_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_chlorine_nitrate", + "id": "tendency_of_atmosphere_moles_of_chlorine_nitrate", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_chlorine_nitrate", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for chlorine nitrate is ClONO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine.json index 9348306e5..4a41088f7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine", + "id": "tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_clox_expressed_as_chlorine", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Clox\" describes a family of chemical species consisting of inorganic chlorine compounds with the exception of hydrogen chloride (HCl) and chlorine nitrate (ClONO2). The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Clox\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity with a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. Standard names that use the term \"inorganic_chlorine\" are used for quantities that contain all inorganic chlorine species including HCl and ClONO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dichlorine_peroxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dichlorine_peroxide.json index 1bfd767ad..1ea9c3753 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dichlorine_peroxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dichlorine_peroxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_dichlorine_peroxide", + "id": "tendency_of_atmosphere_moles_of_dichlorine_peroxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_dichlorine_peroxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for dichlorine peroxide is Cl2O2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dimethyl_sulfide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dimethyl_sulfide.json index bc5453e81..f48eab6c7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dimethyl_sulfide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dimethyl_sulfide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_dimethyl_sulfide", + "id": "tendency_of_atmosphere_moles_of_dimethyl_sulfide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_dimethyl_sulfide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for dimethyl sulfide is (CH3)2S. Dimethyl sulfide is sometimes referred to as DMS.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dinitrogen_pentoxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dinitrogen_pentoxide.json index 1e81add95..f25e105ca 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dinitrogen_pentoxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_dinitrogen_pentoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_dinitrogen_pentoxide", + "id": "tendency_of_atmosphere_moles_of_dinitrogen_pentoxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_dinitrogen_pentoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for dinitrogen pentoxide is N2O5.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethane.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethane.json index b6f2fd91c..1239a2098 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethane.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_ethane", + "id": "tendency_of_atmosphere_moles_of_ethane", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_ethane", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethane is C2H6. Ethane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethanol.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethanol.json index 27798d8e3..080a4be44 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethanol.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethanol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_ethanol", + "id": "tendency_of_atmosphere_moles_of_ethanol", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_ethanol", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethanol is C2H5OH.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethene.json index 2aa29f634..6ab87277b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_ethene", + "id": "tendency_of_atmosphere_moles_of_ethene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_ethene", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethene is C2H4. Ethene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethyne.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethyne.json index aaeedf1c8..160db66a3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethyne.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ethyne.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_ethyne", + "id": "tendency_of_atmosphere_moles_of_ethyne", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_ethyne", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ethyne is HC2H. Ethyne is the IUPAC name for this species, which is also commonly known as acetylene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formaldehyde.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formaldehyde.json index aeb9ec521..ef31451e9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formaldehyde.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formaldehyde.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_formaldehyde", + "id": "tendency_of_atmosphere_moles_of_formaldehyde", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_formaldehyde", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formic_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formic_acid.json index 05b99ee67..b80ab94ef 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formic_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_formic_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_formic_acid", + "id": "tendency_of_atmosphere_moles_of_formic_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_formic_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for formic acid is HCOOH. The IUPAC name for formic acid is methanoic acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_divalent_mercury.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_divalent_mercury.json index f85d777ad..a12e61aa7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_divalent_mercury.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_divalent_mercury.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_gaseous_divalent_mercury", + "id": "tendency_of_atmosphere_moles_of_gaseous_divalent_mercury", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_gaseous_divalent_mercury", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Divalent mercury\" means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_elemental_mercury.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_elemental_mercury.json index 0a986574e..e4f8dc74e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_elemental_mercury.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_gaseous_elemental_mercury.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_gaseous_elemental_mercury", + "id": "tendency_of_atmosphere_moles_of_gaseous_elemental_mercury", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_gaseous_elemental_mercury", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for mercury is Hg.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1202.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1202.json index 310857530..e5b1759e9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1202.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1202.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_halon1202", + "id": "tendency_of_atmosphere_moles_of_halon1202", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_halon1202", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon1202 is CBr2F2. The IUPAC name for Halon1202 is dibromo(difluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1211.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1211.json index 0d8bc9eb7..9fc60fe87 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1211.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1211.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_halon1211", + "id": "tendency_of_atmosphere_moles_of_halon1211", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_halon1211", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon1211 is CBrClF2. The IUPAC name for Halon1211 is bromo-chloro-difluoromethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1301.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1301.json index 489af3ae8..4807b3190 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1301.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon1301.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_halon1301", + "id": "tendency_of_atmosphere_moles_of_halon1301", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_halon1301", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon1301 is CBrF3. The IUPAC name for Halon1301 is bromo(trifluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon2402.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon2402.json index 3965a8906..4fd36681b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon2402.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_halon2402.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_halon2402", + "id": "tendency_of_atmosphere_moles_of_halon2402", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_halon2402", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for Halon2402 is C2Br2F4. The IUPAC name for Halon2402 is 1,2-dibromo-1,1,2,2-tetrafluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcc140a.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcc140a.json index 0168a059a..17854bef3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcc140a.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcc140a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hcc140a", + "id": "tendency_of_atmosphere_moles_of_hcc140a", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hcc140a", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc141b.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc141b.json index 5daf05ac5..2ec391262 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc141b.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc141b.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hcfc141b", + "id": "tendency_of_atmosphere_moles_of_hcfc141b", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hcfc141b", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCFC141b is CH3CCl2F. The IUPAC name for HCFC141b is 1,1-dichloro-1-fluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc142b.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc142b.json index e2ad1eed6..069d35759 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc142b.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc142b.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hcfc142b", + "id": "tendency_of_atmosphere_moles_of_hcfc142b", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hcfc142b", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCFC142b is CH3CClF2. The IUPAC name for HCFC142b is 1-chloro-1,1-difluoroethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc22.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc22.json index 1c4cd655d..daf33ff89 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc22.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hcfc22.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hcfc22", + "id": "tendency_of_atmosphere_moles_of_hcfc22", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hcfc22", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hexachlorobiphenyl.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hexachlorobiphenyl.json index 466e48557..a21a755b6 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hexachlorobiphenyl.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hexachlorobiphenyl.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hexachlorobiphenyl", + "id": "tendency_of_atmosphere_moles_of_hexachlorobiphenyl", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hexachlorobiphenyl", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hexachlorobiphenyl is C12H4Cl6. This structure of this species consists of two linked benzene rings, each of which is additionally bonded to three chlorine atoms.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen.json index 14c3f07db..394a5f0de 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen", + "id": "tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hox_expressed_as_hydrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"HOx\" means a combination of two radical species containing hydrogen and oxygen: OH and HO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_bromide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_bromide.json index f24f79990..5cdf3cd3c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_bromide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hydrogen_bromide", + "id": "tendency_of_atmosphere_moles_of_hydrogen_bromide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hydrogen_bromide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen bromide is HBr.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_chloride.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_chloride.json index 453dc92fd..fcd889724 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_chloride.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hydrogen_chloride", + "id": "tendency_of_atmosphere_moles_of_hydrogen_chloride", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hydrogen_chloride", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen chloride is HCl.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_cyanide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_cyanide.json index fbd00c9d4..bdff4d18c 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_cyanide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_cyanide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hydrogen_cyanide", + "id": "tendency_of_atmosphere_moles_of_hydrogen_cyanide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hydrogen_cyanide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen cyanide is HCN.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_peroxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_peroxide.json index e50294f30..a1247395d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_peroxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydrogen_peroxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hydrogen_peroxide", + "id": "tendency_of_atmosphere_moles_of_hydrogen_peroxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hydrogen_peroxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hydrogen peroxide is H2O2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroperoxyl_radical.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroperoxyl_radical.json index 4017cc2f7..3dea4b49a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroperoxyl_radical.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroperoxyl_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hydroperoxyl_radical", + "id": "tendency_of_atmosphere_moles_of_hydroperoxyl_radical", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hydroperoxyl_radical", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for the hydroperoxyl radical is HO2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroxyl_radical.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroxyl_radical.json index 581f6eca3..39a3954df 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroxyl_radical.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hydroxyl_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hydroxyl_radical", + "id": "tendency_of_atmosphere_moles_of_hydroxyl_radical", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hydroxyl_radical", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for the hydroxyl radical is OH. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypobromous_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypobromous_acid.json index c2713400a..dad752b08 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypobromous_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypobromous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hypobromous_acid", + "id": "tendency_of_atmosphere_moles_of_hypobromous_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hypobromous_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hypobromous acid is HOBr.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypochlorous_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypochlorous_acid.json index 59f26bf81..118ceec7a 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypochlorous_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_hypochlorous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_hypochlorous_acid", + "id": "tendency_of_atmosphere_moles_of_hypochlorous_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_hypochlorous_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for hypochlorous acid is HOCl.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_bromine.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_bromine.json index 321d9c277..498e36101 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_bromine.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_bromine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_inorganic_bromine", + "id": "tendency_of_atmosphere_moles_of_inorganic_bromine", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_inorganic_bromine", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Inorganic bromine\", sometimes referred to as Bry, describes a family of chemical species which result from the degradation of source gases containing bromine (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea salt and other aerosols. \"Inorganic bromine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"brox\" are used for quantities that contain all inorganic bromine species except HBr and BrONO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_chlorine.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_chlorine.json index e555cb5fd..3215a81fb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_chlorine.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_inorganic_chlorine.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_inorganic_chlorine", + "id": "tendency_of_atmosphere_moles_of_inorganic_chlorine", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_inorganic_chlorine", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Inorganic chlorine\", sometimes referred to as Cly, describes a family of chemical species which result from the degradation of source gases containing chlorine (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea salt and other aerosols. \"Inorganic chlorine\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. Standard names that use the term \"clox\" are used for quantities that contain all inorganic chlorine species except HCl and ClONO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_isoprene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_isoprene.json index 868f32098..dea618653 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_isoprene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_isoprene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_isoprene", + "id": "tendency_of_atmosphere_moles_of_isoprene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_isoprene", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for isoprene is CH2=C(CH3)CH=CH2. The IUPAC name for isoprene is 2-methylbuta-1,3-diene. Isoprene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_limonene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_limonene.json index 29baa171c..b53a90a2d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_limonene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_limonene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_limonene", + "id": "tendency_of_atmosphere_moles_of_limonene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_limonene", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for limonene is C10H16. The IUPAC name for limonene is 1-methyl-4-prop-1-en-2-ylcyclohexene. Limonene is a member of the group of hydrocarbons known as terpenes. There are standard names for the terpene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methane.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methane.json index dd1cb2adf..fd43c7ad9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methane.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_methane", + "id": "tendency_of_atmosphere_moles_of_methane", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_methane", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere,i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methanol.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methanol.json index a0d007025..d19921dfb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methanol.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methanol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_methanol", + "id": "tendency_of_atmosphere_moles_of_methanol", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_methanol", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methanol is CH3OH.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_bromide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_bromide.json index 9f54cbbd3..131ca1191 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_bromide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_methyl_bromide", + "id": "tendency_of_atmosphere_moles_of_methyl_bromide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_methyl_bromide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere,i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_chloride.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_chloride.json index b0765b4a1..9cd96b5ef 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_chloride.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_methyl_chloride", + "id": "tendency_of_atmosphere_moles_of_methyl_chloride", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_methyl_chloride", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe. The chemical formula of methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_hydroperoxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_hydroperoxide.json index 301fa44b3..3ac4f2893 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_hydroperoxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_hydroperoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_methyl_hydroperoxide", + "id": "tendency_of_atmosphere_moles_of_methyl_hydroperoxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_methyl_hydroperoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl hydroperoxide is CH3OOH.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_peroxy_radical.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_peroxy_radical.json index a23c43859..d6bcefc4f 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_peroxy_radical.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_methyl_peroxy_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_methyl_peroxy_radical", + "id": "tendency_of_atmosphere_moles_of_methyl_peroxy_radical", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_methyl_peroxy_radical", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for methyl_peroxy_radical is CH3O2. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_molecular_hydrogen.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_molecular_hydrogen.json index 1696d95a3..caff41296 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_molecular_hydrogen.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_molecular_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_molecular_hydrogen", + "id": "tendency_of_atmosphere_moles_of_molecular_hydrogen", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_molecular_hydrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe. The chemical formula of molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrate_radical.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrate_radical.json index 1b1f61889..b5e8b87e9 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrate_radical.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrate_radical.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitrate_radical", + "id": "tendency_of_atmosphere_moles_of_nitrate_radical", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitrate_radical", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrate is NO3. In chemistry, a \"radical\" is a highly reactive, and therefore short lived, species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid.json index daa7998d9..deb156a8e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitric_acid", + "id": "tendency_of_atmosphere_moles_of_nitric_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitric_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitric acid is HNO3.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json index 57ad2be91..0fb064cdb 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles", + "id": "tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitric_acid_trihydrate_ambient_aerosol_particles", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for nitric acid is HNO3. Nitric acid trihydrate, sometimes referred to as NAT, is a stable crystalline substance consisting of three molecules of water to one molecule of nitric acid.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_dioxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_dioxide.json index 85c1cd62e..9dde2da02 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_dioxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitrogen_dioxide", + "id": "tendency_of_atmosphere_moles_of_nitrogen_dioxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitrogen_dioxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrogen dioxide is NO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_monoxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_monoxide.json index 87df8baa1..ffe407b6e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_monoxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrogen_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitrogen_monoxide", + "id": "tendency_of_atmosphere_moles_of_nitrogen_monoxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitrogen_monoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrogen monoxide is NO.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_acid.json index bf93ed738..f7fdd11fa 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitrous_acid", + "id": "tendency_of_atmosphere_moles_of_nitrous_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitrous_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for nitrous acid is HNO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_oxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_oxide.json index 633151a5b..177b65902 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_oxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nitrous_oxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nitrous_oxide", + "id": "tendency_of_atmosphere_moles_of_nitrous_oxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nitrous_oxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe. The chemical formula of nitrous oxide is N2O.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon.json index 090aee798..10f856e45 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon", + "id": "tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nmvoc_expressed_as_carbon", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"nmvoc\" means non methane volatile organic compounds; \"nmvoc\" is the term used in standard names to describe the group of chemical species having this classification that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen.json index d7da2c56c..e37b4a720 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen", + "id": "tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen.json index fefdb37a8..46ffd9bd4 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen", + "id": "tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_noy_expressed_as_nitrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Noy\" describes a family of chemical species. The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) , chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)). The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ozone.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ozone.json index a13aa5f10..ec5163af7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ozone.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_ozone", + "id": "tendency_of_atmosphere_moles_of_ozone", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_ozone", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for ozone is O3.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate.json index 559bcd879..f46ecdf84 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate", + "id": "tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_peroxyacetyl_nitrate", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for peroxyacetyl nitrate, sometimes referred to as PAN, is CH3COO2NO2. The IUPAC name for peroxyacetyl_nitrate is nitroethaneperoxoate.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxynitric_acid.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxynitric_acid.json index d1da701b9..7ac99d4fe 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxynitric_acid.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_peroxynitric_acid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_peroxynitric_acid", + "id": "tendency_of_atmosphere_moles_of_peroxynitric_acid", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_peroxynitric_acid", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for peroxynitric acid, sometimes referred to as PNA, is HO2NO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propane.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propane.json index e96f71cad..ec5b84cb7 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propane.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_propane", + "id": "tendency_of_atmosphere_moles_of_propane", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_propane", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for propane is C3H8. Propane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propene.json index 8fd117049..b0614368d 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_propene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_propene", + "id": "tendency_of_atmosphere_moles_of_propene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_propene", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for propene is C3H6. Propene is a member of the group of hydrocarbons known as alkenes. There are standard names for the alkene group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_radon.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_radon.json index 8f66572d4..c73a75027 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_radon.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_radon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_radon", + "id": "tendency_of_atmosphere_moles_of_radon", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_radon", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical symbol for radon is Rn.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles.json index 82d392a09..deaa60bdf 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles", + "id": "tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_sulfate_dry_aerosol_particles", "description": "The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the sulfate anion is SO4(2-).", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfur_dioxide.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfur_dioxide.json index 3c123f3ab..821bafd5b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfur_dioxide.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_sulfur_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_sulfur_dioxide", + "id": "tendency_of_atmosphere_moles_of_sulfur_dioxide", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_sulfur_dioxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_toluene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_toluene.json index 90dd6679b..f84308250 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_toluene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_toluene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_toluene", + "id": "tendency_of_atmosphere_moles_of_toluene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_toluene", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for toluene is C6H5CH3. Toluene has the same structure as benzene, except that one of the hydrogen atoms is replaced by a methyl group. The IUPAC name for toluene is methylbenzene.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_water_vapor.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_water_vapor.json index 76a4e386f..3635e6d3b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_water_vapor.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_water_vapor", + "id": "tendency_of_atmosphere_moles_of_water_vapor", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_water_vapor", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_xylene.json b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_xylene.json index cd15f92f3..28bbe7579 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_xylene.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_moles_of_xylene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_moles_of_xylene", + "id": "tendency_of_atmosphere_moles_of_xylene", "type": "standard_name", "name": "tendency_of_atmosphere_moles_of_xylene", "description": "\"tendency_of_X\" means derivative of X with respect to time. The construction \"atmosphere_moles_of_X\" means the total number of moles of X in the entire atmosphere, i.e. summed over the atmospheric column and over the entire globe. The chemical formula for xylene is C6H4C2H6. In chemistry, xylene is a generic term for a group of three isomers of dimethylbenzene. The IUPAC names for the isomers are 1,2-dimethylbenzene, 1,3-dimethylbenzene and 1,4-dimethylbenzene. Xylene is an aromatic hydrocarbon. There are standard names that refer to aromatic_compounds as a group, as well as those for individual species.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition.json index 5ab07f505..0c40939c2 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition", + "id": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dry deposition\" is the sum of turbulent deposition and gravitational settling. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling.json b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling.json index 6449dbade..adff65b2e 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling", + "id": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling", "type": "standard_name", "name": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_gravitational_settling", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition.json index 404943814..12f58586b 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition", + "id": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_turbulent_deposition", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The specification of a physical process by the phrase \"due_to_ \" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The sum of turbulent deposition and gravitational settling is dry deposition.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition.json index 8e618cc39..e9b776278 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition", + "id": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_atmosphere_number_content_of_aerosol_particles_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Wet deposition\" means deposition by precipitation. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_atmosphere_potential_energy_content_due_to_advection.json b/data_descriptors/standard_name/tendency_of_atmosphere_potential_energy_content_due_to_advection.json index 48ed40330..8572b34d3 100644 --- a/data_descriptors/standard_name/tendency_of_atmosphere_potential_energy_content_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_atmosphere_potential_energy_content_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_atmosphere_potential_energy_content_due_to_advection", + "id": "tendency_of_atmosphere_potential_energy_content_due_to_advection", "type": "standard_name", "name": "tendency_of_atmosphere_potential_energy_content_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"atmosphere content\" of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/tendency_of_bedrock_altitude.json b/data_descriptors/standard_name/tendency_of_bedrock_altitude.json index 1ec44b885..9831282e9 100644 --- a/data_descriptors/standard_name/tendency_of_bedrock_altitude.json +++ b/data_descriptors/standard_name/tendency_of_bedrock_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_bedrock_altitude", + "id": "tendency_of_bedrock_altitude", "type": "standard_name", "name": "tendency_of_bedrock_altitude", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. \"Bedrock\" is the solid Earth surface beneath land ice, ocean water or soil.", diff --git a/data_descriptors/standard_name/tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation.json b/data_descriptors/standard_name/tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation.json index e6b31fc75..de3cf00e2 100644 --- a/data_descriptors/standard_name/tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation.json +++ b/data_descriptors/standard_name/tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation", + "id": "tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation", "type": "standard_name", "name": "tendency_of_canopy_water_amount_due_to_evaporation_of_intercepted_precipitation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Water\" means water in all phases. \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\"). Canopy interception is the precipitation, including snow, that is intercepted by the canopy of a tree and then evaporates from the leaves. Evaporation of intercepted precipitation excludes plant transpiration and evaporation from the surface beneath the canopy.", diff --git a/data_descriptors/standard_name/tendency_of_change_in_land_ice_amount.json b/data_descriptors/standard_name/tendency_of_change_in_land_ice_amount.json index ebf8bb04b..71027f5ba 100644 --- a/data_descriptors/standard_name/tendency_of_change_in_land_ice_amount.json +++ b/data_descriptors/standard_name/tendency_of_change_in_land_ice_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_change_in_land_ice_amount", + "id": "tendency_of_change_in_land_ice_amount", "type": "standard_name", "name": "tendency_of_change_in_land_ice_amount", "description": "\"Amount\" means mass per unit area. Zero change in land ice amount is an arbitrary level. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_dry_energy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/tendency_of_dry_energy_content_of_atmosphere_layer.json index 3ad3cd7de..759a724d0 100644 --- a/data_descriptors/standard_name/tendency_of_dry_energy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/tendency_of_dry_energy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_dry_energy_content_of_atmosphere_layer", + "id": "tendency_of_dry_energy_content_of_atmosphere_layer", "type": "standard_name", "name": "tendency_of_dry_energy_content_of_atmosphere_layer", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/tendency_of_dry_static_energy_content_of_atmosphere_layer.json b/data_descriptors/standard_name/tendency_of_dry_static_energy_content_of_atmosphere_layer.json index b5c81d0a0..25e1367b3 100644 --- a/data_descriptors/standard_name/tendency_of_dry_static_energy_content_of_atmosphere_layer.json +++ b/data_descriptors/standard_name/tendency_of_dry_static_energy_content_of_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_dry_static_energy_content_of_atmosphere_layer", + "id": "tendency_of_dry_static_energy_content_of_atmosphere_layer", "type": "standard_name", "name": "tendency_of_dry_static_energy_content_of_atmosphere_layer", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind.json b/data_descriptors/standard_name/tendency_of_eastward_wind.json index b476d1fb5..fa7a82bdb 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind", + "id": "tendency_of_eastward_wind", "type": "standard_name", "name": "tendency_of_eastward_wind", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection.json index 0b808ecff..4993a7faf 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_advection", + "id": "tendency_of_eastward_wind_due_to_advection", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity.json index 727b78849..e7abb5066 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity", + "id": "tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The \"Transformed Eulerian Mean\" refers to a formulation of the mean equations which incorporates some eddy terms into the definition of the mean, described in Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity.json index 202cfcbb3..667e3f99a 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity", + "id": "tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The \"Transformed Eulerian Mean\" refers to a formulation of the mean equations which incorporates some eddy terms into the definition of the mean, described in Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_convection.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_convection.json index c4233136d..d1225c479 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_convection", + "id": "tendency_of_eastward_wind_due_to_convection", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_diffusion.json index 83aea5c1d..0fc695886 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_diffusion", + "id": "tendency_of_eastward_wind_due_to_diffusion", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence.json index 4e68cceaa..64a802ed3 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence", + "id": "tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Eliassen Palm flux\" is a widely used vector in the meridional plane, and the divergence of this flux appears as a forcing in the Transformed Eulerian mean formulation of the zonal mean zonal wind equation. Thus, \"eastward_wind\" here will generally be the zonally averaged eastward wind.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_gravity_wave_drag.json index e7e936cc9..1f280d578 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_gravity_wave_drag", + "id": "tendency_of_eastward_wind_due_to_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_gravity_wave_drag", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The quantity named tendency_of_eastward_wind_due_to_gravity_wave_drag is the sum of the tendencies due to orographic and nonorographic gravity waves which have standard names of tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag and tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag, respectively.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag.json index 5eb2da4be..64d934222 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", + "id": "tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The total tendency of the eastward wind due to gravity waves has the standard name tendency_of_eastward_wind_due_to_gravity_wave_drag. It is the sum of the tendencies due to orographic gravity waves and nonorographic waves. The tendency of eastward wind due to orographic gravity waves has the standard name tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_numerical_artefacts.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_numerical_artefacts.json index fe69d58ae..a1e0b929c 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_numerical_artefacts.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_numerical_artefacts.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_numerical_artefacts", + "id": "tendency_of_eastward_wind_due_to_numerical_artefacts", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_numerical_artefacts", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The total tendency of the eastward wind will include a variety of numerical and diffusive effects: a variable with this standard name is sometimes needed to allow the momentum budget to be closed.", diff --git a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag.json index 4fd4653c9..df007fc9a 100644 --- a/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag", + "id": "tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). The total tendency of the eastward wind due to gravity waves has the standard name tendency_of_eastward_wind_due_to_gravity_wave_drag. It is the sum of the tendencies due to orographic gravity waves and nonorographic waves. The tendency of eastward wind due to nonorographic gravity waves has the standard name tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag.", diff --git a/data_descriptors/standard_name/tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection.json b/data_descriptors/standard_name/tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection.json index e2b483214..82ebd8313 100644 --- a/data_descriptors/standard_name/tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection", + "id": "tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection", "type": "standard_name", "name": "tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.", diff --git a/data_descriptors/standard_name/tendency_of_global_average_sea_level_change.json b/data_descriptors/standard_name/tendency_of_global_average_sea_level_change.json index 47a066c15..138048afc 100644 --- a/data_descriptors/standard_name/tendency_of_global_average_sea_level_change.json +++ b/data_descriptors/standard_name/tendency_of_global_average_sea_level_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_global_average_sea_level_change", + "id": "tendency_of_global_average_sea_level_change", "type": "standard_name", "name": "tendency_of_global_average_sea_level_change", "description": "Global average sea level change is due to change in volume of the water in the ocean, caused by mass and/or density change, or to change in the volume of the ocean basins, caused by tectonics etc. It is sometimes called \"eustatic\", which is a term that also has other definitions. It differs from the change in the global average sea surface height relative to the centre of the Earth by the global average vertical movement of the ocean floor. Zero sea level change is an arbitrary level. \"tendency_of_X\" means derivative of X with respect to time. Because global average sea level change quantifies the change in volume of the world ocean, it is not calculated necessarily by considering local changes in mean sea level.", diff --git a/data_descriptors/standard_name/tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection.json b/data_descriptors/standard_name/tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection.json index dde50a0da..dd33b1b2f 100644 --- a/data_descriptors/standard_name/tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection", + "id": "tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection", "type": "standard_name", "name": "tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/tendency_of_land_ice_mass.json b/data_descriptors/standard_name/tendency_of_land_ice_mass.json index 08d51781b..0f027cf9a 100644 --- a/data_descriptors/standard_name/tendency_of_land_ice_mass.json +++ b/data_descriptors/standard_name/tendency_of_land_ice_mass.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_land_ice_mass", + "id": "tendency_of_land_ice_mass", "type": "standard_name", "name": "tendency_of_land_ice_mass", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The horizontal domain over which the quantity is calculated is described by the associated coordinate variables and coordinate bounds or by a coordinate variable or scalar coordinate variable with the standard name of \"region\" supplied according to section 6.1.1 of the CF conventions.", diff --git a/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_basal_mass_balance.json b/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_basal_mass_balance.json index 05b50e21a..7db6e2409 100644 --- a/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_basal_mass_balance.json +++ b/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_basal_mass_balance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_land_ice_mass_due_to_basal_mass_balance", + "id": "tendency_of_land_ice_mass_due_to_basal_mass_balance", "type": "standard_name", "name": "tendency_of_land_ice_mass_due_to_basal_mass_balance", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Mass balance means the net rate at which ice is accumulated. A negative value means loss of ice. The tendency in ice mass due to the basal mass balance is the spatial integral of the quantity with standard name land_ice_basal_specific_mass_balance_flux. The geographical extent of the ice over which the mass is calculated is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\".", diff --git a/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_calving.json b/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_calving.json index 26ac8cf4a..5b576205f 100644 --- a/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_calving.json +++ b/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_calving.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_land_ice_mass_due_to_calving", + "id": "tendency_of_land_ice_mass_due_to_calving", "type": "standard_name", "name": "tendency_of_land_ice_mass_due_to_calving", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The tendency in ice mass due to calving is the spatial integral of the quantity named land_ice_specific_mass_flux_due_to_calving. The geographical extent over which the quantity is calculated is defined by the horizontal coordinates and any associated coordinate bounds or by a string valued auxiliary coordinate variable with a standard name of \"region\".", diff --git a/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_surface_mass_balance.json b/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_surface_mass_balance.json index 341e56946..f5c460043 100644 --- a/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_surface_mass_balance.json +++ b/data_descriptors/standard_name/tendency_of_land_ice_mass_due_to_surface_mass_balance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_land_ice_mass_due_to_surface_mass_balance", + "id": "tendency_of_land_ice_mass_due_to_surface_mass_balance", "type": "standard_name", "name": "tendency_of_land_ice_mass_due_to_surface_mass_balance", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The phrase \"tendency_of_X\" means derivative of X with respect to time. The surface called \"surface\" means the lower boundary of the atmosphere. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Mass balance\" means the net rate at which ice is added. A negative value means loss of ice. The tendency in ice mass due to the surface mass balance is the spatial integral of the quantity with standard name land_ice_surface_specific_mass_balance_flux. The horizontal domain over which the quantity is described by the associated coordinate variables and coordinate bounds or by a string valued coordinate variable or scalar coordinate variable with a standard name of \"region\".", diff --git a/data_descriptors/standard_name/tendency_of_land_ice_thickness.json b/data_descriptors/standard_name/tendency_of_land_ice_thickness.json index 415b925bd..d87a32852 100644 --- a/data_descriptors/standard_name/tendency_of_land_ice_thickness.json +++ b/data_descriptors/standard_name/tendency_of_land_ice_thickness.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_land_ice_thickness", + "id": "tendency_of_land_ice_thickness", "type": "standard_name", "name": "tendency_of_land_ice_thickness", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. \"Thickness\" means the vertical extent of a layer..", diff --git a/data_descriptors/standard_name/tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation.json b/data_descriptors/standard_name/tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation.json index 19abdf363..f576c240f 100644 --- a/data_descriptors/standard_name/tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation.json +++ b/data_descriptors/standard_name/tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation", + "id": "tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation", "type": "standard_name", "name": "tendency_of_mass_concentration_of_elemental_carbon_dry_aerosol_particles_in_air_due_to_emission_from_aviation", "description": "\"tendency_of_X\" means derivative of X with respect to time. Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The mass is the total mass of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. \"Dry aerosol particles\" means aerosol particles without any water uptake. The \"aviation\" sector includes fuel combustion activities related to civil aviation. \"Aviation\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3a as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\". Chemically, \"elemental carbon\" is the carbonaceous fraction of particulate matter that is thermally stable in an inert atmosphere to high temperatures near 4000K and can only be gasified by oxidation starting at temperatures above 340 C. It is assumed to be inert and non-volatile under atmospheric conditions and insoluble in any solvent (Ogren and Charlson, 1983).", diff --git a/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation.json b/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation.json index 0a0d9dd31..b8750aaa8 100644 --- a/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation.json +++ b/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation", + "id": "tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation", "type": "standard_name", "name": "tendency_of_mass_concentration_of_nitrogen_dioxide_in_air_due_to_emission_from_aviation", "description": "\"tendency_of_X\" means derivative of X with respect to time. Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen dioxide is NO2. The \"aviation\" sector includes fuel combustion activities related to civil aviation. \"Aviation\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3a as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json b/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json index 133fc16b8..b212702d3 100644 --- a/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json +++ b/data_descriptors/standard_name/tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation", + "id": "tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation", "type": "standard_name", "name": "tendency_of_mass_concentration_of_nitrogen_monoxide_in_air_due_to_emission_from_aviation", "description": "\"tendency_of_X\" means derivative of X with respect to time. Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The mass is the total mass of the molecules. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. The chemical formula for nitrogen monoxide is NO. The \"aviation\" sector includes fuel combustion activities related to civil aviation. \"Aviation\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3a as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json b/data_descriptors/standard_name/tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json index 0f32b6c5c..da3f086be 100644 --- a/data_descriptors/standard_name/tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json +++ b/data_descriptors/standard_name/tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation", + "id": "tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation", "type": "standard_name", "name": "tendency_of_mass_concentration_of_nox_expressed_as_nitrogen_monoxide_in_air_due_to_emission_from_aviation", "description": "\"tendency_of_X\" means derivative of X with respect to time. Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Emission\" means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface). \"Emission\" is a process entirely distinct from \"re-emission\" which is used in some standard names. \"Nox\" means a combination of two radical species containing nitrogen and oxygen: NO+NO2. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The \"aviation\" sector includes fuel combustion activities related to civil aviation. \"Aviation\" is the term used in standard names to describe a collection of emission sources. A variable which has this value for the standard_name attribute should be accompanied by a comment attribute which lists the source categories and provides a reference to the categorization scheme, for example, \"IPCC (Intergovernmental Panel on Climate Change) source category 1A3a as defined in the 2006 IPCC guidelines for national greenhouse gas inventories\".", diff --git a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer.json b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer.json index eb3c13636..f0d4eed3f 100644 --- a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer.json +++ b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer", + "id": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer", "type": "standard_name", "name": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection.json b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection.json index c14b700cf..7040efdf9 100644 --- a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection", + "id": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection", "type": "standard_name", "name": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection.json b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection.json index 1397cd9b6..c82901e9a 100644 --- a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection.json +++ b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection", + "id": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection", "type": "standard_name", "name": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_deep_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection.json b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection.json index e50b9bfb4..2dad0b554 100644 --- a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection.json +++ b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection", + "id": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection", "type": "standard_name", "name": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_shallow_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well.", diff --git a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence.json b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence.json index 013c718ee..163f5f151 100644 --- a/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence.json +++ b/data_descriptors/standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence", + "id": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence", "type": "standard_name", "name": "tendency_of_mass_content_of_water_vapor_in_atmosphere_layer_due_to_turbulence", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary variable) as well.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air.json index 171b810c9..33cdd43ba 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air", + "id": "tendency_of_mass_fraction_of_cloud_condensed_water_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_condensed_water_in_air", "description": "\"Tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). \"Condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection.json index 6e427ae70..d420ad9a1 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection", + "id": "tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"condensed_water\" means liquid and ice. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air.json index a01b5dfcf..dbca08622 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air", + "id": "tendency_of_mass_fraction_of_cloud_ice_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_ice_in_air", "description": "\"tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection.json index 983bf53fa..9da19ec81 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection", + "id": "tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion.json index ec1f800fb..aa9863684 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion", + "id": "tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air.json index 6f07fb514..174a9e779 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air", + "id": "tendency_of_mass_fraction_of_cloud_liquid_water_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_liquid_water_in_air", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection.json index 64da25f71..6120e2fbb 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection", + "id": "tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion.json index d5c5d8bd2..3ec9ecb3c 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion", + "id": "tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion", "type": "standard_name", "name": "tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_ice_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_ice_in_air.json index 96ac3af31..45e58d047 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_ice_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_ice_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_convective_cloud_ice_in_air", + "id": "tendency_of_mass_fraction_of_convective_cloud_ice_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_convective_cloud_ice_in_air", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Convective cloud is that produced by the convection schemes in an atmosphere model.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air.json index d8a5eabc1..e8b718e99 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air", + "id": "tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_convective_cloud_liquid_water_in_air", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". Convective cloud is that produced by the convection schemes in an atmosphere model. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air.json index 29ebc56a7..f08e113c2 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The phrase \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection.json index 61b74fcaf..87c52cf81 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_advection", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain.json index 8df573328..65115b39d 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_rain", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Autoconversion is the process of collision and coalescence which results in the formation of precipitation particles from cloud water droplets or ice crystals. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow.json index 32be9f25f..ffbd58737 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_autoconversion_to_snow", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Autoconversion is the process of collision and coalescence which results in the formation of precipitation particles from cloud water droplets or ice crystals. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing.json index fabb5a4d9..5fc1b128b 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"condensed_water\" means liquid and ice. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics.json index 044aa78f3..861fb3a85 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_cloud_microphysics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The phrase \"condensed_water\" means liquid and ice. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Cloud microphysics\" is the sum of many cloud processes such as condensation, evaporation, homogeneous nucleation, heterogeneous nucleation, deposition, sublimation, the Bergeron-Findeisen process, riming, accretion, aggregation and icefall. The precise list of processes that are included in \"cloud microphysics\" can vary between models. Where possible, the data variable should be accompanied by a complete description of the processes included, for example, by using a comment attribute. Standard names also exist to describe the tendencies due to the separate processes.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation.json index be2feaa7f..bfc54d1ce 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_condensation_and_evaporation", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) Condensation is the conversion of vapor into liquid. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall.json index 79f0905b4..f9e2496bf 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_condensed_water_in_air_due_to_icefall", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air.json index 50ee0c599..b48f22376 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow.json index 848101c9a..95bba98fe 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_accretion_to_snow", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Accretion is the growth of a hydrometeor by collision with cloud droplets or ice crystals. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection.json index 9048a5ada..3cd11bc01 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_advection", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation.json index f8e9d6dfe..9de414740 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_aggregation", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Aggregation is the clumping together of frozen cloud particles to produce snowflakes. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid.json index 104bd0f8e..fb8863994 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_bergeron_findeisen_process_from_cloud_liquid", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The Bergeron-Findeisen process is the conversion of cloud liquid water to cloud ice arising from the fact that water vapor has a lower equilibrium vapor pressure with respect to ice than it has with respect to liquid water at the same subfreezing temperature.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing.json index b7d26181c..eecd54de0 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics.json index 68d17fe61..d410ebef2 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_cloud_microphysics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mass fraction is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Cloud microphysics\" is the sum of many cloud processes such as condensation, evaporation, homogeneous nucleation, heterogeneous nucleation, deposition, sublimation, the Bergeron-Findeisen process, riming, accretion, aggregation and icefall. The precise list of processes that are included in \"cloud microphysics\" can vary between models. Where possible, the data variable should be accompanied by a complete description of the processes included, for example, by using a comment attribute. Standard names also exist to describe the tendencies due to the separate processes.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment.json index 72b6b2def..1357e0e0b 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_convective_detrainment", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation.json index 77c0cdb7c..4cce58967 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_deposition_and_sublimation", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Sublimation is the conversion of solid into vapor. Deposition is the opposite of sublimation, i.e. it is the conversion of vapor into solid. Deposition is distinct from the processes of dry deposition and wet deposition of atmospheric aerosol particles, which are referred to in some standard names. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice.json index d8018b4de..8d195d084 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_evaporation_of_melting_ice", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water.json index 9916861d8..c20fa298b 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_cloud_liquid_water", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterogeneous nucleation occurs when a small particle of a substance other than water acts as a freezing or condensation nucleus. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor.json index 382908807..279092d95 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_heterogeneous_nucleation_from_water_vapor", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterogeneous nucleation occurs when a small particle of a substance other than water acts as a freezing or condensation nucleus.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation.json index c5a6db188..4c2c9b23e 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_homogeneous_nucleation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Homogeneous nucleation occurs when a small number of water molecules combine to form a freezing or condensation nucleus.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall.json index af8485f4f..39b9ce6b2 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_icefall", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water.json index a74eb4344..969c4c2f1 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_cloud_liquid_water", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain.json index e3b0a6fa2..3f878be9a 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_melting_to_rain", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water.json index a98323e0e..d8944e753 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_cloud_liquid_water", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Riming is the rapid freezing of supercooled water onto a surface. \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain.json index 58d5cbae7..a8279723a 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_ice_in_air_due_to_riming_from_rain", "description": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Riming is the rapid freezing of supercooled water onto a surface. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air.json index b09024d5a..ebeb17da1 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain.json index dc43d67d6..9037858e9 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_rain", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Accretion is the growth of a hydrometeor by collision with cloud droplets or ice crystals. \"Rain\" means drops of water falling through the atmosphere that have a diameter greater than 0.5 mm.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow.json index 5adb1e318..af287577f 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_accretion_to_snow", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\" where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Accretion is the growth of a hydrometeor by collision with cloud droplets or ice crystals.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection.json index 65327c0f4..5b860da73 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion.json index 9e985af1a..7f4194de3 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_autoconversion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Autoconversion is the process of collision and coalescence which results in the formation of precipitation particles from cloud water droplets or ice crystals.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice.json index 00da248d0..bbf8ff0d4 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_bergeron_findeisen_process_to_cloud_ice", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The Bergeron-Findeisen process is the conversion of cloud liquid water to cloud ice arising from the fact that water vapor has a lower equilibrium vapor pressure with respect to ice than it has with respect to liquid water at the same subfreezing temperature.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing.json index 135559c69..55e88d07d 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics.json index 02c23d703..63d4ed8ef 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_cloud_microphysics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Cloud microphysics\" is the sum of many cloud processes such as condensation, evaporation, homogeneous nucleation, heterogeneous nucleation, deposition, sublimation, the Bergeron-Findeisen process, riming, accretion, aggregation and icefall. The precise list of processes that are included in \"cloud microphysics\" can vary between models. Where possible, the data variable should be accompanied by a complete description of the processes included, for example, by using a comment attribute. Standard names also exist to describe the tendencies due to the separate processes.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation.json index bfe4c1ab4..ece152caa 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing.json index a22c68e1e..e810742ee 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection.json index e6f11bffa..d63179c13 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_convection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating.json index 358d685c3..a13ddbf4d 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_longwave_heating", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor. The term \"longwave\" means longwave radiation.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change.json index f8c3295f1..1f804dcab 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_pressure_change", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating.json index 7f34129ba..c967e93da 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_shortwave_heating", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor. The term \"shortwave\" means shortwave radiation.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence.json index 0b77a188e..8f0a8cd26 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_condensation_and_evaporation_from_turbulence", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Condensation is the conversion of vapor into liquid. Evaporation is the conversion of liquid or solid into vapor.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment.json index 354db8787..30fa1cd8a 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_convective_detrainment", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation.json index 3b3bd41d5..a2629add7 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_heterogeneous_nucleation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Heterogeneous nucleation occurs when a small particle of a substance other than water acts as a freezing or condensation nucleus.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation.json index 14439370d..b272dd74a 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_homogeneous_nucleation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Homogeneous nucleation occurs when a small number of water molecules combine to form a freezing or condensation nucleus.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice.json index 1c12d417a..c4552f006 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_melting_from_cloud_ice", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming.json b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming.json index e778f7a99..6fbdcf11f 100644 --- a/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming.json +++ b/data_descriptors/standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming", + "id": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming", "type": "standard_name", "name": "tendency_of_mass_fraction_of_stratiform_cloud_liquid_water_in_air_due_to_riming", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mass fraction\" is used in the construction \"mass_fraction_of_X_in_Y\", where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). A chemical species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Cloud liquid water\" refers to the liquid phase of cloud water. A diameter of 0.2 mm has been suggested as an upper limit to the size of drops that shall be regarded as cloud drops; larger drops fall rapidly enough so that only very strong updrafts can sustain them. Any such division is somewhat arbitrary, and active cumulus clouds sometimes contain cloud drops much larger than this. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Cloud_drop. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Riming is the rapid freezing of supercooled water onto a surface.", diff --git a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_carbon_monoxide.json b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_carbon_monoxide.json index 797d15a42..37ab73600 100644 --- a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_carbon_monoxide.json +++ b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_carbon_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_middle_atmosphere_moles_of_carbon_monoxide", + "id": "tendency_of_middle_atmosphere_moles_of_carbon_monoxide", "type": "standard_name", "name": "tendency_of_middle_atmosphere_moles_of_carbon_monoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"middle_atmosphere_moles_of_X\" means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_hcc140a.json b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_hcc140a.json index a7d98f058..fa75fdfd4 100644 --- a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_hcc140a.json +++ b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_hcc140a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_middle_atmosphere_moles_of_hcc140a", + "id": "tendency_of_middle_atmosphere_moles_of_hcc140a", "type": "standard_name", "name": "tendency_of_middle_atmosphere_moles_of_hcc140a", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"middle_atmosphere_moles_of_X\" means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methane.json b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methane.json index 8d008c026..3a2042a98 100644 --- a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methane.json +++ b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_middle_atmosphere_moles_of_methane", + "id": "tendency_of_middle_atmosphere_moles_of_methane", "type": "standard_name", "name": "tendency_of_middle_atmosphere_moles_of_methane", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"middle_atmosphere_moles_of_X\" means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of methane is CH4.", diff --git a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_bromide.json b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_bromide.json index 71542d420..e7b86127e 100644 --- a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_bromide.json +++ b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_middle_atmosphere_moles_of_methyl_bromide", + "id": "tendency_of_middle_atmosphere_moles_of_methyl_bromide", "type": "standard_name", "name": "tendency_of_middle_atmosphere_moles_of_methyl_bromide", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"middle_atmosphere_moles_of_X\" means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of methyl bromide is CH3Br.", diff --git a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_chloride.json b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_chloride.json index c22a06dc4..7ee521a5f 100644 --- a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_chloride.json +++ b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_methyl_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_middle_atmosphere_moles_of_methyl_chloride", + "id": "tendency_of_middle_atmosphere_moles_of_methyl_chloride", "type": "standard_name", "name": "tendency_of_middle_atmosphere_moles_of_methyl_chloride", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"middle_atmosphere_moles_of_X\" means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of methyl chloride is CH3Cl.", diff --git a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_molecular_hydrogen.json b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_molecular_hydrogen.json index b23e3dcff..26e1c6463 100644 --- a/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_molecular_hydrogen.json +++ b/data_descriptors/standard_name/tendency_of_middle_atmosphere_moles_of_molecular_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_middle_atmosphere_moles_of_molecular_hydrogen", + "id": "tendency_of_middle_atmosphere_moles_of_molecular_hydrogen", "type": "standard_name", "name": "tendency_of_middle_atmosphere_moles_of_molecular_hydrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"middle_atmosphere_moles_of_X\" means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production.json index 25aed891b..ddaa3170d 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production", + "id": "tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production", "type": "standard_name", "name": "tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution.json index 0785aec19..2fca9b3ca 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution", + "id": "tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution", "type": "standard_name", "name": "tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production.json index 7250e345c..57f77eb2a 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production", + "id": "tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production", "type": "standard_name", "name": "tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution.json index 025c98c31..aac0c2c87 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution", + "id": "tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution", "type": "standard_name", "name": "tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes.json index 699e4c797..86833e136 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes", + "id": "tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes.json index 7757a258a..53652d5d4 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes", + "id": "tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dissolved inorganic iron\" means iron ions, in oxidation states of both Fe2+ and Fe3+, in solution.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes.json index 36a426ab2..ff87a7854 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes", + "id": "tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Inorganic nitrogen\" describes a family of chemical species which, in an ocean model, usually includes nitrite, nitrate and ammonium which act as nitrogen nutrients. \"Inorganic nitrogen\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes.json index f229cba97..e61283dab 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes", + "id": "tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dissolved inorganic phosphorus\" means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes.json index 058848746..7bf4e4e01 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes", + "id": "tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dissolved inorganic silicon\" means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles.json index 22f487cfd..feede99dc 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles", + "id": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles", "description": "The quantity with standard name tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles is the change in concentration caused by the processes of dissolution, remineralization and desorption of iron back to the dissolved phase.The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton.json index acdde5c9f..6c9024dee 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton", + "id": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_grazing_of_phytoplankton", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Grazing of phytoplankton\" means the grazing of phytoplankton by zooplankton.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles.json index 8af92fb93..fc4971366 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles", + "id": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles", "type": "standard_name", "name": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production.json index 689cb1348..f77467b8d 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production", + "id": "tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production", "type": "standard_name", "name": "tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production.json index d2aa74497..010276f5a 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production", + "id": "tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production", "type": "standard_name", "name": "tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The term \"ox\" means a combination of three radical species containing 1 or 3 oxygen atoms: O + O1d + O3. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"chemical and photolytic production\" means the result of all chemical and photolytic reactions within the medium (here, atmosphere) that produce a certain amount of the particular species.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction.json index 5c67ad508..42ab3d739 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction", + "id": "tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction", "type": "standard_name", "name": "tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The term \"ox\" means a combination of three radical species containing 1 or 3 oxygen atoms: O + O1d + O3. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Chemical destruction\" means the result of all chemical reactions within the medium (here, atmosphere) that remove a certain amount of a particular species from the medium.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton.json index ed342b382..9ddfeb3a0 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Grazing of phytoplankton\" means the grazing of phytoplankton by zooplankton.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production.json index bd14e6e2c..b0794d764 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\".", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae.json index 6ca8951c2..dae6d6907 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_algae", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Particulate means suspended solids of all sizes. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\".", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton.json index 38293a7af..425772b33 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". \"Calcareous phytoplankton\" are phytoplankton that produce calcite. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms.json index 275345490..5e47789bc 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". Diatoms are single-celled phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton.json index 294e344cc..cb7e90abd 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophic_phytoplankton", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Mole concentration\" means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical species or biological group denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction \"A_expressed_as_B\", where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. Diazotrophic phytoplankton are phytoplankton (predominantly from Phylum Cyanobacteria) that are able to fix molecular nitrogen (gas or solute) in addition to nitrate and ammonium.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton.json index ce1d5a051..9467fb2e9 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. \"Miscellaneous phytoplankton\" are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton.json index e2db0d243..a1afe2f6c 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization.json index 285f2738a..4634c4b62 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization", "description": "Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Nitrate utilization\" means net primary production of carbon by phytoplankton based on nitrate alone. \"Production of carbon\" means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (the rate of synthesis of biomass from inorganic precursors) by autotrophs (\"producers\"), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. In the oceans, carbon production per unit volume is often found at a number of depths at a given horizontal location. That quantity can then be integrated to calculate production per unit area at the location. Standard names for production per unit area use the term \"productivity\". \"tendency_of_X\" means derivative of X with respect to time. The chemical formula for the nitrate anion is NO3-.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization.json index 1883bc758..ec442fa07 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization", + "id": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization", "type": "standard_name", "name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization", "description": "\"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called \"molarity\", and is used in the construction \"mole_concentration_of_X_in_Y\", where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Remineralization is the degradation of organic matter into inorganic forms of carbon, nitrogen, phosphorus and other micronutrients, which consumes oxygen and releases energy.", diff --git a/data_descriptors/standard_name/tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production.json index cce5f826e..1652f2b7d 100644 --- a/data_descriptors/standard_name/tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production", + "id": "tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production", "type": "standard_name", "name": "tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Mole concentration means number of moles per unit volume, also called\"molarity\", and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as \"nitrogen\" or a phrase such as \"nox_expressed_as_nitrogen\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind.json b/data_descriptors/standard_name/tendency_of_northward_wind.json index 256b14260..cc0e6b785 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind", + "id": "tendency_of_northward_wind", "type": "standard_name", "name": "tendency_of_northward_wind", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_advection.json b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_advection.json index d3e49c223..4f0ddff58 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind_due_to_advection", + "id": "tendency_of_northward_wind_due_to_advection", "type": "standard_name", "name": "tendency_of_northward_wind_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_convection.json b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_convection.json index 291e90153..4802e72a6 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind_due_to_convection", + "id": "tendency_of_northward_wind_due_to_convection", "type": "standard_name", "name": "tendency_of_northward_wind_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_diffusion.json index c1b72a43c..d5f17b7b8 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind_due_to_diffusion", + "id": "tendency_of_northward_wind_due_to_diffusion", "type": "standard_name", "name": "tendency_of_northward_wind_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_gravity_wave_drag.json index 7dc0c2b13..f15b46643 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind_due_to_gravity_wave_drag", + "id": "tendency_of_northward_wind_due_to_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_northward_wind_due_to_gravity_wave_drag", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The quantity with standard name tendency_of_northward_wind_due_to_gravity_wave_drag is the total tendency of the northward wind due to gravity waves. It is the sum of the tendencies due to orographic and nonorographic gravity waves which have the standard names tendency_of_northward_wind_due_to_orographic_gravity_wave_drag and tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag, respectively.", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag.json index d864b5ece..a99bdeb28 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag", + "id": "tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Nonorographic\" gravity waves refer to gravity waves which are not generated by flow over orography. The quantity with standard name tendency_of_northward_wind_due_to_gravity_wave_drag is the total tendency of the northward wind due to gravity waves. It is the sum of the tendencies due to orographic and nonorographic gravity waves which have the standard names tendency_of_northward_wind_due_to_orographic_gravity_wave_drag and tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag, respectively.", diff --git a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_orographic_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_orographic_gravity_wave_drag.json index 98b50b79f..b7583f4b0 100644 --- a/data_descriptors/standard_name/tendency_of_northward_wind_due_to_orographic_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_northward_wind_due_to_orographic_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_northward_wind_due_to_orographic_gravity_wave_drag", + "id": "tendency_of_northward_wind_due_to_orographic_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_northward_wind_due_to_orographic_gravity_wave_drag", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\"). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Orographic gravity waves\" refer to gravity waves which are generated by flow over orography. The quantity with standard name tendency_of_northward_wind_due_to_gravity_wave_drag is the total tendency of the northward wind due to gravity waves. It is the sum of the tendencies due to orographic and nonorographic gravity waves which have the standard names tendency_of_northward_wind_due_to_orographic_gravity_wave_drag and tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag, respectively.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_barotropic_streamfunction.json b/data_descriptors/standard_name/tendency_of_ocean_barotropic_streamfunction.json index 8a43eb781..cfec2388e 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_barotropic_streamfunction.json +++ b/data_descriptors/standard_name/tendency_of_ocean_barotropic_streamfunction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_barotropic_streamfunction", + "id": "tendency_of_ocean_barotropic_streamfunction", "type": "standard_name", "name": "tendency_of_ocean_barotropic_streamfunction", "description": "\"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection.json index 30ab9c6c5..acdbd0364 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection", + "id": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production.json index 08347c09e..8e36e84bb 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production", + "id": "tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production", "description": "\"Content\" indicates a quantity per unit area. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production.json index c11497fe7..9be19c692 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production", + "id": "tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production", "description": "\"Content\" indicates a quantity per unit area. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution.json index ff4e07724..06de208c9 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution", + "id": "tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_carbon_due_to_runoff_and_sediment_dissolution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation.json index f460347c7..b89d71585 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation", + "id": "tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_carbon_due_to_sedimentation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon.json index d82179996..6db1efd4f 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes.json index 364661d6d..dc4ddb893 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dissolved inorganic carbon\" describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. \"Dissolved inorganic carbon\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron.json index 0f505139c..c96627f0b 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron", "description": "\"Content\" indicates a quantity per unit area. \"tendency_of_X\" means derivative of X with respect to time. \"Dissolved inorganic iron\" means iron ions, in oxidation states of both Fe2+ and Fe3+, in solution.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes.json index 239b8faa1..00764b5a7 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dissolved inorganic iron\" means iron ions, in oxidation states of both Fe2+ and Fe3+, in solution.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen.json index ebde5cbaa..958d2a70c 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"tendency_of_X\" means derivative of X with respect to time. \"Inorganic nitrogen\" describes a family of chemical species which, in an ocean model, usually includes nitrite, nitrate and ammonium which act as nitrogen nutrients. \"Inorganic nitrogen\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variableshould be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes.json index 064d71087..1016d3747 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes", "description": "\"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Inorganic nitrogen\" describes a family of chemical species which, in an ocean model, usually includes nitrite, nitrate and ammonium which act as nitrogen nutrients. \"Inorganic nitrogen\" is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus.json index c06ef9c40..3b92a7230 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus", "description": "\"Content\" indicates a quantity per unit area. \"tendency_of_X\" means derivative of X with respect to time. \"Dissolved inorganic phosphorus\" means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes.json index 7fc48b763..976109eed 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes", "description": "\"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dissolved inorganic phosphorus\" means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon.json index 3ea0c8189..028b355c1 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon", "description": "\"Content\" indicates a quantity per unit area. \"tendency_of_X\" means derivative of X with respect to time. \"Dissolved inorganic silicon\" means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes.json index febe3b89a..1fa5d4e15 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes", + "id": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes", "description": "\"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Dissolved inorganic silicon\" means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json index 7cbb3a8d3..3946693fc 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", + "id": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Denitrification\" is the conversion of nitrate into gaseous compounds such as nitric oxide, nitrous oxide and molecular nitrogen which are then emitted to the atmosphere. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff.json index a70fc68be..c08b2784c 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff", + "id": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Deposition of nitrogen into the ocean is the sum of dry and wet deposition of nitrogen species onto the ocean surface from the atmosphere. \"Nitrogen fixation\" means the production of ammonia from nitrogen gas. Organisms that fix nitrogen are termed \"diazotrophs\". Diazotrophic phytoplankton can fix atmospheric nitrogen, thus increasing the content of nitrogen in the ocean. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation.json index 99270f87a..2dba0ac3d 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation", + "id": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Nitrogen fixation\" means the production of ammonia from nitrogen gas. Organisms that fix nitrogen are termed \"diazotrophs\". Diazotrophic phytoplankton can fix atmospheric nitrogen, thus increasing the content of nitrogen in the ocean.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon.json index 823f0441d..332d24fcb 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon", + "id": "tendency_of_ocean_mole_content_of_inorganic_carbon", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_inorganic_carbon", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Inorganic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution.json index b9f7be104..4e5869398 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution", + "id": "tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Inorganic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json index f94c4210d..770ae0047 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", + "id": "tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Inorganic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_biological_production.json index 15bc6f2d2..58905c936 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_iron_due_to_biological_production", + "id": "tendency_of_ocean_mole_content_of_iron_due_to_biological_production", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_iron_due_to_biological_production", "description": "\"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution.json index 3e6c92ade..ff466eb2c 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution", + "id": "tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json index b61116d9c..1243e5ec5 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_iron_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", + "id": "tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", "description": "\"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production.json index 4c4eb3c06..85b2a97c2 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production", + "id": "tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Nitrogen\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution.json index eeadc9dfb..9876f3ec3 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution", + "id": "tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Runoff is the liquid water which drains from land. If not specified, \"runoff\" refers to the sum of surface runoff and subsurface drainage.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json index dfa35c523..829d8597e 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", + "id": "tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Organic carbon\" describes a family of chemical species and is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sedimentation\" is the sinking of particulate matter to the floor of a body of water.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json index 178c6c5a5..5ea697175 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", + "id": "tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Deposition of nitrogen into the ocean is the sum of dry and wet deposition of the considered species onto the ocean surface from the atmosphere. \"Oxidized nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state greater than zero. Usually, particle bound and gaseous nitrogen compounds, such as nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json index ebd37ff66..59db48097 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", + "id": "tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"dry_deposition\" is the sum of turbulent deposition and gravitational settling of the considered species onto the ocean surface from the atmosphere. \"Oxidized nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state greater than zero. Usually, particle bound and gaseous nitrogen compounds, such as nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json index 0add9e829..387874cce 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", + "id": "tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_oxidized_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"wet_deposition\" means deposition by precipitation. \"Oxidized nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state greater than zero. Usually, particle bound and gaseous nitrogen compounds, such as nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), nitrate (NO3-), peroxynitric acid (HNO4), bromine nitrate (BrONO2), chlorine nitrate (ClONO2) and organic nitrates (most notably peroxyacetyl nitrate, sometimes referred to as PAN, (CH3COO2NO2)), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production.json index 36e2ed7fa..367c4230a 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production", + "id": "tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json index 517613dcc..8b75e5c18 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", + "id": "tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Deposition of nitrogen into the ocean is the sum of dry and wet deposition of nitrogen species onto the ocean surface from the atmosphere. \"Reduced nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state less than zero. Usually, particle bound and gaseous nitrogen compounds, primarily ammonium (NH4+) and ammonia (NH3), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json index e4ca61031..f9c4abf7b 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", + "id": "tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_dry_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"dry_deposition\" is the sum of turbulent deposition and gravitational settling of the considered species onto the ocean surface from the atmosphere. \"Reduced nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state less than zero. Usually, particle bound and gaseous nitrogen compounds, primarily ammonium (NH4+) and ammonia (NH3), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json index 2263f1497..addfaa8e3 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", + "id": "tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_reduced_nitrogen_compounds_expressed_as_nitrogen_due_to_wet_deposition", "description": "\"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"wet_deposition\" means deposition by precipitation. \"Reduced nitrogen compounds\" means all chemical species containing nitrogen atoms with an oxidation state less than zero. Usually, particle bound and gaseous nitrogen compounds, primarily ammonium (NH4+) and ammonia (NH3), are included. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_silicon_due_to_biological_production.json b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_silicon_due_to_biological_production.json index a8f4d5845..0ca2e68a3 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_silicon_due_to_biological_production.json +++ b/data_descriptors/standard_name/tendency_of_ocean_mole_content_of_silicon_due_to_biological_production.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_mole_content_of_silicon_due_to_biological_production", + "id": "tendency_of_ocean_mole_content_of_silicon_due_to_biological_production", "type": "standard_name", "name": "tendency_of_ocean_mole_content_of_silicon_due_to_biological_production", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"ocean content\" of a quantity refers to the vertical integral from the surface to the bottom of the ocean. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content.json b/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content.json index e9b727b01..67c7f71a3 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content.json +++ b/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_potential_energy_content", + "id": "tendency_of_ocean_potential_energy_content", "type": "standard_name", "name": "tendency_of_ocean_potential_energy_content", "description": "\"Content\" indicates a quantity per unit area. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.) \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_background.json b/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_background.json index d0e0e7b06..d76a712e1 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_background.json +++ b/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_background.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_potential_energy_content_due_to_background", + "id": "tendency_of_ocean_potential_energy_content_due_to_background", "type": "standard_name", "name": "tendency_of_ocean_potential_energy_content_due_to_background", "description": "\"Content\" indicates a quantity per unit area. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.) \"Due to background\" means caused by a time invariant imposed field which may be either constant over the globe or spatially varying, depending on the ocean model used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_tides.json b/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_tides.json index 97ed851ec..31ca473be 100644 --- a/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_tides.json +++ b/data_descriptors/standard_name/tendency_of_ocean_potential_energy_content_due_to_tides.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_ocean_potential_energy_content_due_to_tides", + "id": "tendency_of_ocean_potential_energy_content_due_to_tides", "type": "standard_name", "name": "tendency_of_ocean_potential_energy_content_due_to_tides", "description": "\"Content\" indicates a quantity per unit area. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.) \"Due to tides\" means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time.", diff --git a/data_descriptors/standard_name/tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection.json b/data_descriptors/standard_name/tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection.json index feec9b018..29caa42f4 100644 --- a/data_descriptors/standard_name/tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection", + "id": "tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection", "type": "standard_name", "name": "tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_convection.json b/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_convection.json index bafa3aaa2..d3663ef2e 100644 --- a/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_convection", + "id": "tendency_of_potential_energy_content_of_ocean_layer_due_to_convection", "type": "standard_name", "name": "tendency_of_potential_energy_content_of_ocean_layer_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion.json index 5ecfee472..e15aaf9ed 100644 --- a/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion", + "id": "tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion", "type": "standard_name", "name": "tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Layer\" means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.)", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_basal_melting.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_basal_melting.json index 4b911185a..2bb07d68a 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_basal_melting.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_basal_melting.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_basal_melting", + "id": "tendency_of_sea_ice_amount_due_to_basal_melting", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_basal_melting", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation.json index 5dbcdd300..8be8015a0 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation", + "id": "tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Congelation ice\" means the freezing of sea water onto the underside of thin, new sea ice that has been formed by small areas of frazil ice crystals joining together into a continuous layer at the sea surface. Congelation ice forms under calm water conditions; it thickens and stabilizes the layer of sea ice and produces a smooth bottom surface.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice.json index f05026444..c0a3824ba 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice", + "id": "tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Conversion of snow to sea ice\" occurs when the mass of snow accumulated on an area of sea ice is sufficient to cause the ice to become mostly submerged. Waves can then wash over the ice and snow surface and freeze into a layer that becomes \"snow ice\".", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads.json index 94140ead2..8f23b82f7 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads", + "id": "tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Frazil\" consists of needle like crystals of ice, typically between three and four millimeters in diameter, which form as sea water begins to freeze. Salt is expelled during the freezing process and frazil ice consists of nearly pure fresh water. Leads are stretches of open water within wider areas of sea ice.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes.json index 9794ebf11..ca49dca9f 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes", + "id": "tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_lateral_growth_of_ice_floes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. An ice floe is a flat expanse of sea ice, generally taken to be less than 10 km across. \"Lateral growth of ice floe\" means the accumulation of ice at the extreme edges of the ice area.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_melting.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_melting.json index 010870418..0d06b5734 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_melting.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_lateral_melting.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_lateral_melting", + "id": "tendency_of_sea_ice_amount_due_to_lateral_melting", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_lateral_melting", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_dynamics.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_dynamics.json index ca9d7107f..071a35866 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_dynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_dynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_dynamics", + "id": "tendency_of_sea_ice_amount_due_to_sea_ice_dynamics", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_sea_ice_dynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice dynamics\" refers to advection of sea ice.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics.json index 2f34d1c42..0904f9880 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics", + "id": "tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_surface_melting.json b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_surface_melting.json index 99b40062c..becce12a0 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_surface_melting.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_amount_due_to_surface_melting.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_amount_due_to_surface_melting", + "id": "tendency_of_sea_ice_amount_due_to_surface_melting", "type": "standard_name", "name": "tendency_of_sea_ice_amount_due_to_surface_melting", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_dynamics.json b/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_dynamics.json index 9ea47b685..1a8b5375c 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_dynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_dynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_area_fraction_due_to_dynamics", + "id": "tendency_of_sea_ice_area_fraction_due_to_dynamics", "type": "standard_name", "name": "tendency_of_sea_ice_area_fraction_due_to_dynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called \"sea ice concentration\". \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice dynamics\" refers to the motion of sea ice.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_ridging.json b/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_ridging.json index 40fa02c76..bb5508a5d 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_ridging.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_ridging.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_area_fraction_due_to_ridging", + "id": "tendency_of_sea_ice_area_fraction_due_to_ridging", "type": "standard_name", "name": "tendency_of_sea_ice_area_fraction_due_to_ridging", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called \"sea ice concentration\". \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sea ice \"ridging\" occurs in rough sea conditions. The motion of the sea surface can cause areas of sea ice to deform and fold resulting in ridged upper and lower surfaces. The ridges can be as much as twenty metres thick if thick ice is deformed.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_thermodynamics.json b/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_thermodynamics.json index eeb1ccbd6..eb8704ebb 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_thermodynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_area_fraction_due_to_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_area_fraction_due_to_thermodynamics", + "id": "tendency_of_sea_ice_area_fraction_due_to_thermodynamics", "type": "standard_name", "name": "tendency_of_sea_ice_area_fraction_due_to_thermodynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called \"sea ice concentration\". \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_dynamics.json b/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_dynamics.json index abf9f49c7..35ba35eea 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_dynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_dynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_thickness_due_to_dynamics", + "id": "tendency_of_sea_ice_thickness_due_to_dynamics", "type": "standard_name", "name": "tendency_of_sea_ice_thickness_due_to_dynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Thickness\" means the vertical extent of a layer. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice dynamics\" refers to the motion of sea ice.", diff --git a/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_thermodynamics.json b/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_thermodynamics.json index 028816c4c..08a7d3580 100644 --- a/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_thermodynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_ice_thickness_due_to_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_ice_thickness_due_to_thermodynamics", + "id": "tendency_of_sea_ice_thickness_due_to_thermodynamics", "type": "standard_name", "name": "tendency_of_sea_ice_thickness_due_to_thermodynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Thickness\" means the vertical extent of a layer. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes.", diff --git a/data_descriptors/standard_name/tendency_of_sea_surface_height_above_mean_sea_level.json b/data_descriptors/standard_name/tendency_of_sea_surface_height_above_mean_sea_level.json index 228a13136..3fcd79f93 100644 --- a/data_descriptors/standard_name/tendency_of_sea_surface_height_above_mean_sea_level.json +++ b/data_descriptors/standard_name/tendency_of_sea_surface_height_above_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_surface_height_above_mean_sea_level", + "id": "tendency_of_sea_surface_height_above_mean_sea_level", "type": "standard_name", "name": "tendency_of_sea_surface_height_above_mean_sea_level", "description": "\"Sea surface height\" is a time-varying quantity. \"tendency_of_X\" means derivative of X with respect to time. \"Height_above_X\" means the vertical distance above the named surface X. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The standard name for the height of the sea surface above the geoid is sea_surface_height_above_geoid. The standard name for the height of the sea surface above the reference ellipsoid is sea_surface_height_above_reference_ellipsoid.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json b/data_descriptors/standard_name/tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json index 1671d03f2..be3b71dfc 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", + "id": "tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", "type": "standard_name", "name": "tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. sea_water_alkalinity_expressed_as_mole_equivalent is the total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content.json index 0c6e56ba2..5f4c8e784 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. This tendency encompasses all processes that impact on the time changes for the heat content within a grid cell. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json index 4bb1bafda..e9e82a93b 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dianeutral mixing\" means mixing across surfaces of neutral buoyancy. \"Parameterized\" means the part due to a scheme representing processes which are not explicitly resolved by the model.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json index 7c01b6c68..cb0b67adf 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json index 16e3c08c2..c9eca8506 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json index 6d0bf815e..a1d6c05b0 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddy diffusive processes include diffusion along neutral directions in the interior of the ocean and horizontal diffusion in the surface boundary layer. The processes occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json index bde1cdb22..bc37a6891 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized submesoscale eddy advection occurs on a spatial scale of the order of 1 km horizontally. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. There are also standard names for parameterized_mesoscale_eddy_advection which, along with parameterized_submesoscale_eddy_advection, contributes to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json index c7b800e9d..8e155b06e 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection", + "id": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "type": "standard_name", "name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the conservative temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). Conservative Temperature is specific potential enthalpy (which has the standard name sea_water_specific_potential_enthalpy) divided by a fixed value of the specific heat capacity of sea water, namely cp_0 = 3991.86795711963 J kg-1 K-1. Conservative Temperature is a more accurate measure of the \"heat content\" of sea water, by a factor of one hundred, than is potential temperature. Because of this, it can be regarded as being proportional to the heat content of sea water per unit mass. Reference: www.teos-10.org; McDougall, 2003 doi: 10.1175/1520-0485(2003)033<0945:PEACOV>2.0.CO;2. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"residual_mean_advection\" refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content.json index 6baafa1dc..9e385eda9 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. This tendency encompasses all processes that impact on the time changes for the heat content within a grid cell. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json index 71b6be2f6..a16746372 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dianeutral mixing\" means mixing across surfaces of neutral buoyancy. \"Parameterized\" means the part due to a scheme representing processes which are not explicitly resolved by the model.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json index 4e90e7b6d..e61374582 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json index d63f560e3..08480952e 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json index d47bf800e..abe3d82f6 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddy diffusive processes include diffusion along neutral directions in the interior of the ocean and horizontal diffusion in the surface boundary layer. The processes occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json index e2c9df0cf..9c8982f0d 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized submesoscale eddy advection occurs on a spatial scale of the order of 1 km horizontally. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. There are also standard names for parameterized_mesoscale_eddy_advection which, along with parameterized_submesoscale_eddy_advection, contributes to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json index 6e2dc4ac4..de5b0c1c5 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection", + "id": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "type": "standard_name", "name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The phrase \"expressed_as_heat_content\" means that this quantity is calculated as the specific heat capacity times density of sea water multiplied by the potential temperature of the sea water in the grid cell and integrated over depth. If used for a layer heat content, coordinate bounds should be used to define the extent of the layers. If no coordinate bounds are specified, it is assumed that the integral is calculated over the entire vertical extent of the medium, e.g, if the medium is sea water the integral is assumed to be calculated over the full depth of the ocean. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"residual_mean_advection\" refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity.json index e65fb1d39..e9168d131 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity", + "id": "tendency_of_sea_water_salinity", "type": "standard_name", "name": "tendency_of_sea_water_salinity", "description": "\"tendency_of_X\" means derivative of X with respect to time. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_advection.json index 5d835e35f..4143bd25b 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_due_to_advection", + "id": "tendency_of_sea_water_salinity_due_to_advection", "type": "standard_name", "name": "tendency_of_sea_water_salinity_due_to_advection", "description": "\"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_horizontal_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_horizontal_mixing.json index f1ec34fb8..c67868cb9 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_horizontal_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_horizontal_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_due_to_horizontal_mixing", + "id": "tendency_of_sea_water_salinity_due_to_horizontal_mixing", "type": "standard_name", "name": "tendency_of_sea_water_salinity_due_to_horizontal_mixing", "description": "\"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Horizontal mixing\" means any horizontal transport other than by advection and parameterized eddy advection, usually represented as horizontal diffusion in ocean models. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection.json index 4a1ff258b..d0524f2a6 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection", + "id": "tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_salinity_due_to_parameterized_eddy_advection", "description": "\"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics.json index bcdf4ea2a..f6778402e 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics", + "id": "tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of sea ice mass due to surface and basal fluxes, i.e. due to melting, sublimation and fusion. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_vertical_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_vertical_mixing.json index b9cb991a8..a0c0fa141 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_vertical_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_due_to_vertical_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_due_to_vertical_mixing", + "id": "tendency_of_sea_water_salinity_due_to_vertical_mixing", "type": "standard_name", "name": "tendency_of_sea_water_salinity_due_to_vertical_mixing", "description": "\"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Vertical mixing\" means any vertical transport other than by advection and parameterized eddy advection, represented by a combination of vertical diffusion, turbulent mixing and convection in ocean models. Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and normally given as 1e-3 or 0.001 i.e. parts per thousand. There are standard names for the more precisely defined salinity quantities: sea_water_knudsen_salinity, S_K (used for salinity observations between 1901 and 1966), sea_water_cox_salinity, S_C (used for salinity observations between 1967 and 1977), sea_water_practical_salinity, S_P (used for salinity observations from 1978 to the present day), sea_water_absolute_salinity, S_A, sea_water_preformed_salinity, S_*, and sea_water_reference_salinity. Practical Salinity is reported on the Practical Salinity Scale of 1978 (PSS-78), and is usually based on the electrical conductivity of sea water in observations since the 1960s. Conversion of data between the observed scales follows: S_P = (S_K - 0.03) * (1.80655 / 1.805) and S_P = S_C, however the accuracy of the latter is dependent on whether chlorinity or conductivity was used to determine the S_C value, with this inconsistency driving the development of PSS-78. The more precise standard names should be used where appropriate for both modelled and observed salinities. In particular, the use of sea_water_salinity to describe salinity observations made from 1978 onwards is now deprecated in favor of the term sea_water_practical_salinity which is the salinity quantity stored by national data centers for post-1978 observations. The only exception to this is where the observed salinities are definitely known not to be recorded on the Practical Salinity Scale. The unit \"parts per thousand\" was used for sea_water_knudsen_salinity and sea_water_cox_salinity.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content.json index 7b1009972..3d568ca06 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content", "description": "\"Content\" indicates a quantity per unit area. \"tendency_of_X\" means derivative of X with respect to time. This tendency encompasses all processes that impact on the time changes for the salt content within a grid cell.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing.json index bd0454b2f..4a2a83fbe 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Dianeutral mixing\" means mixing across surfaces of neutral buoyancy. \"Parameterized\" means the part due to a scheme representing processes which are not explicitly resolved by the model.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection.json index 7571b7913..bf32db912 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection.json index 3ffe9ea3a..6a8c1def2 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddy advection is represented in ocean models using schemes such as the Gent-McWilliams scheme. There are also standard names for parameterized_submesoscale_eddy_advection which, along with parameterized_mesoscale_eddy_advection, contributes to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion.json index 8b33c7e96..ef2e1b3fc 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddy diffusive processes include diffusion along neutral directions in the interior of the ocean and horizontal diffusion in the surface boundary layer. The processes occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection.json index 79da21b0c..8d28b0b34 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized submesoscale eddy advection occurs on a spatial scale of the order of 1 km horizontally. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. There are also standard names for parameterized_mesoscale_eddy_advection which, along with parameterized_submesoscale_eddy_advection, contributes to the total parameterized eddy advection. Additionally, when the parameterized advective process is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic. The convergence of a skew-flux is identical (in the continuous formulation) to the convergence of an advective flux, making their tendencies the same.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection.json index 48de36324..e3da4a63a 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection", + "id": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection", "type": "standard_name", "name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The phrase \"residual_mean_advection\" refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_temperature.json b/data_descriptors/standard_name/tendency_of_sea_water_temperature.json index cb4cc6955..650f5be10 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_temperature.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_temperature", + "id": "tendency_of_sea_water_temperature", "type": "standard_name", "name": "tendency_of_sea_water_temperature", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Sea water temperature is the in situ temperature of the sea water. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_advection.json index f69435fdf..e62b0d3d4 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_temperature_due_to_advection", + "id": "tendency_of_sea_water_temperature_due_to_advection", "type": "standard_name", "name": "tendency_of_sea_water_temperature_due_to_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Sea water temperature is the in situ temperature of the sea water. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_horizontal_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_horizontal_mixing.json index 078e28eb0..e0ca82bd9 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_horizontal_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_horizontal_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_temperature_due_to_horizontal_mixing", + "id": "tendency_of_sea_water_temperature_due_to_horizontal_mixing", "type": "standard_name", "name": "tendency_of_sea_water_temperature_due_to_horizontal_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Horizontal mixing\" means any horizontal transport other than by advection and parameterized eddy advection, usually represented as horizontal diffusion in ocean models. Sea water temperature is the in situ temperature of the sea water. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection.json b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection.json index 26b5c6a44..78ef18add 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection", + "id": "tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection", "type": "standard_name", "name": "tendency_of_sea_water_temperature_due_to_parameterized_eddy_advection", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized eddy advection in an ocean model means the part due to a scheme representing parameterized eddy-induced advective effects not included in the resolved model velocity field. Parameterized eddy advection can be represented on various spatial scales and there are standard names for parameterized_mesoscale_eddy_advection and parameterized_submesoscale_eddy_advection which both contribute to the total parameterized eddy advection. Sea water temperature is the in situ temperature of the sea water. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_vertical_mixing.json b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_vertical_mixing.json index 3ffc8d979..f49857379 100644 --- a/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_vertical_mixing.json +++ b/data_descriptors/standard_name/tendency_of_sea_water_temperature_due_to_vertical_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_sea_water_temperature_due_to_vertical_mixing", + "id": "tendency_of_sea_water_temperature_due_to_vertical_mixing", "type": "standard_name", "name": "tendency_of_sea_water_temperature_due_to_vertical_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Vertical mixing\" means any vertical transport other than by advection and parameterized eddy advection, represented by a combination of vertical diffusion, turbulent mixing and convection in ocean models. Sea water temperature is the in situ temperature of the sea water. For observed data, depending on the period during which the observation was made, the measured in situ temperature was recorded against standard \"scales\". These historical scales include the International Practical Temperature Scale of 1948 (IPTS-48; 1948-1967), the International Practical Temperature Scale of 1968 (IPTS-68, Barber, 1969; 1968-1989) and the International Temperature Scale of 1990 (ITS-90, Saunders 1990; 1990 onwards). Conversion of data between these scales follows t68 = t48 - (4.4 x 10e-6) * t48(100 - t - 48); t90 = 0.99976 * t68. Observations made prior to 1948 (IPTS-48) have not been documented and therefore a conversion cannot be certain. Differences between t90 and t68 can be up to 0.01 at temperatures of 40 C and above; differences of 0.002-0.007 occur across the standard range of ocean temperatures (-10 - 30 C). The International Equation of State of Seawater 1980 (EOS-80, UNESCO, 1981) and the Practical Salinity Scale (PSS-78) were both based on IPTS-68, while the Thermodynamic Equation of Seawater 2010 (TEOS-10) is based on ITS-90. References: Barber, 1969, doi: 10.1088/0026-1394/5/2/001; UNESCO, 1981; Saunders, 1990, WOCE Newsletter, 10, September 1990. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json b/data_descriptors/standard_name/tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json index 4153ce328..f128eaa13 100644 --- a/data_descriptors/standard_name/tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json +++ b/data_descriptors/standard_name/tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", + "id": "tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", "type": "standard_name", "name": "tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. On land, \"nitrogen fixation\" means the uptake of nitrogen gas directly from the atmosphere. The representation of fixed nitrogen is model dependent, with the nitrogen entering either vegetation, soil or both. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization.json b/data_descriptors/standard_name/tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization.json index a11b96028..830ef84d7 100644 --- a/data_descriptors/standard_name/tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization.json +++ b/data_descriptors/standard_name/tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization", + "id": "tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization", "type": "standard_name", "name": "tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. The \"soil content\" of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including \"content_of_soil_layer\" are used. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The list of individual species that are included in this quantity can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute. \"Fertilization\" means the addition of artificial fertilizers and animal manure to soil for the purpose of increasing plant nutrient concentrations.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity.json b/data_descriptors/standard_name/tendency_of_specific_humidity.json index c063df453..efe812a47 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity", + "id": "tendency_of_specific_humidity", "type": "standard_name", "name": "tendency_of_specific_humidity", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_advection.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_advection.json index 6b7e97509..776776761 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_advection", + "id": "tendency_of_specific_humidity_due_to_advection", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_boundary_layer_mixing.json index edbd1485d..8a915529a 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_boundary_layer_mixing", + "id": "tendency_of_specific_humidity_due_to_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_convection.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_convection.json index 5ef8dc1f3..c0c471abe 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_convection", + "id": "tendency_of_specific_humidity_due_to_convection", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_diffusion.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_diffusion.json index d33b99d87..c7ea7a135 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_diffusion.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_diffusion", + "id": "tendency_of_specific_humidity_due_to_diffusion", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_model_physics.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_model_physics.json index 608c7f7f6..3fe092c67 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_model_physics.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_model_physics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_model_physics", + "id": "tendency_of_specific_humidity_due_to_model_physics", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_model_physics", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. \"specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation.json index e239914b0..007e31b85 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation", + "id": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Specific\" means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. A variable with the standard name of tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation should contain the effects of all processes which convert stratiform clouds and precipitation to or from water vapor.", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json index 77f7c4f04..55b4f27c9 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", + "id": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Specific humidity is the mass fraction of water vapor in (moist) air. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases. \"Boundary layer mixing\" means turbulent motions that transport heat, water, momentum and chemical constituents within the atmospheric boundary layer and affect exchanges between the surface and the atmosphere. The atmospheric boundary layer is typically characterised by a well-mixed sub-cloud layer of order 500 metres, and by a more extended conditionally unstable layer with boundary-layer clouds up to 2 km. (Reference: IPCC Third Assessment Report, Working Group 1: The Scientific Basis, 7.2.2.3, https://archive.ipcc.ch/ipccreports/tar/wg1/273.htm).", diff --git a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_precipitation.json b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_precipitation.json index 3f27cf677..eaa13b7c3 100644 --- a/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_precipitation.json +++ b/data_descriptors/standard_name/tendency_of_specific_humidity_due_to_stratiform_precipitation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_specific_humidity_due_to_stratiform_precipitation", + "id": "tendency_of_specific_humidity_due_to_stratiform_precipitation", "type": "standard_name", "name": "tendency_of_specific_humidity_due_to_stratiform_precipitation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. Specific humidity is the mass fraction of water vapor in (moist) air. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes). \"Precipitation\" in the earth's atmosphere means precipitation of water in all phases.", diff --git a/data_descriptors/standard_name/tendency_of_surface_air_pressure.json b/data_descriptors/standard_name/tendency_of_surface_air_pressure.json index 8ada329e3..60f823555 100644 --- a/data_descriptors/standard_name/tendency_of_surface_air_pressure.json +++ b/data_descriptors/standard_name/tendency_of_surface_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_surface_air_pressure", + "id": "tendency_of_surface_air_pressure", "type": "standard_name", "name": "tendency_of_surface_air_pressure", "description": "The surface called \"surface\" means the lower boundary of the atmosphere. \"tendency_of_X\" means derivative of X with respect to time. Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/tendency_of_surface_snow_amount.json b/data_descriptors/standard_name/tendency_of_surface_snow_amount.json index ec79d4375..dfb9324c1 100644 --- a/data_descriptors/standard_name/tendency_of_surface_snow_amount.json +++ b/data_descriptors/standard_name/tendency_of_surface_snow_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_surface_snow_amount", + "id": "tendency_of_surface_snow_amount", "type": "standard_name", "name": "tendency_of_surface_snow_amount", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice.json b/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice.json index 9a8ba3847..d7abdd75f 100644 --- a/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice.json +++ b/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice", + "id": "tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice", "type": "standard_name", "name": "tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Conversion of snow to sea ice\" occurs when the mass of snow accumulated on an area of sea ice is sufficient to cause the ice to become mostly submerged. Waves can then wash over the ice and snow surface and freeze into a layer that becomes \"snow ice\". \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_drifting_into_sea.json b/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_drifting_into_sea.json index bae22c643..c5fe63fd8 100644 --- a/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_drifting_into_sea.json +++ b/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_drifting_into_sea.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_surface_snow_amount_due_to_drifting_into_sea", + "id": "tendency_of_surface_snow_amount_due_to_drifting_into_sea", "type": "standard_name", "name": "tendency_of_surface_snow_amount_due_to_drifting_into_sea", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_sea_ice_dynamics.json b/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_sea_ice_dynamics.json index bfd074e34..36e5f725a 100644 --- a/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_sea_ice_dynamics.json +++ b/data_descriptors/standard_name/tendency_of_surface_snow_amount_due_to_sea_ice_dynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_surface_snow_amount_due_to_sea_ice_dynamics", + "id": "tendency_of_surface_snow_amount_due_to_sea_ice_dynamics", "type": "standard_name", "name": "tendency_of_surface_snow_amount_due_to_sea_ice_dynamics", "description": "The quantity with standard name tendency_of_surface_snow_amount_due_to_sea_ice_dynamics is the rate of change of snow amount caused by advection of the sea ice upon which the snow is lying. The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Amount\" means mass per unit area. Surface snow amount refers to the amount on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice dynamics\" refers to advection of sea ice. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing.json b/data_descriptors/standard_name/tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing.json index 332787176..256b41899 100644 --- a/data_descriptors/standard_name/tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing.json +++ b/data_descriptors/standard_name/tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing", + "id": "tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing", "type": "standard_name", "name": "tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. Thermal energy is the total vibrational energy, kinetic and potential, of all the molecules and atoms in a substance. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants. The quantity with standard name tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing is the heat energy carried by rainfall reaching the surface. It is calculated relative to the heat that would be carried by rainfall reaching the surface at zero degrees Celsius. It is calculated as the product QrainCpTrain, where Qrain is the mass flux of rainfall reaching the surface (kg m-2 s-1), Cp is the specific heat capacity of water and Train is the temperature in degrees Celsius of the rain water reaching the surface. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_carbon_monoxide.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_carbon_monoxide.json index b3470d49a..2740f710f 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_carbon_monoxide.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_carbon_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_carbon_monoxide", + "id": "tendency_of_troposphere_moles_of_carbon_monoxide", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_carbon_monoxide", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of carbon monoxide is CO.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcc140a.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcc140a.json index 07226e91d..a96165288 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcc140a.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcc140a.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_hcc140a", + "id": "tendency_of_troposphere_moles_of_hcc140a", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_hcc140a", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of HCC140a, also called methyl chloroform, is CH3CCl3. The IUPAC name for HCC140a is 1,1,1-trichloroethane.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcfc22.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcfc22.json index e9e8d5737..9665640cc 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcfc22.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_hcfc22.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_hcfc22", + "id": "tendency_of_troposphere_moles_of_hcfc22", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_hcfc22", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. The construction \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro(difluoro)methane.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methane.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methane.json index bdc96347f..7d830b718 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methane.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methane.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_methane", + "id": "tendency_of_troposphere_moles_of_methane", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_methane", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of methane is CH4. Methane is a member of the group of hydrocarbons known as alkanes. There are standard names for the alkane group as well as for some of the individual species.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_bromide.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_bromide.json index 3183584b8..f28f86ab9 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_bromide.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_bromide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_methyl_bromide", + "id": "tendency_of_troposphere_moles_of_methyl_bromide", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_methyl_bromide", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of methyl bromide is CH3Br. The IUPAC name for methyl bromide is bromomethane.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_chloride.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_chloride.json index a7fa76e82..7d6af6eb1 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_chloride.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_methyl_chloride.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_methyl_chloride", + "id": "tendency_of_troposphere_moles_of_methyl_chloride", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_methyl_chloride", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of methyl chloride is CH3Cl. The IUPAC name for methyl chloride is chloromethane.", diff --git a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_molecular_hydrogen.json b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_molecular_hydrogen.json index 4db0db9b0..e684a488c 100644 --- a/data_descriptors/standard_name/tendency_of_troposphere_moles_of_molecular_hydrogen.json +++ b/data_descriptors/standard_name/tendency_of_troposphere_moles_of_molecular_hydrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_troposphere_moles_of_molecular_hydrogen", + "id": "tendency_of_troposphere_moles_of_molecular_hydrogen", "type": "standard_name", "name": "tendency_of_troposphere_moles_of_molecular_hydrogen", "description": "\"tendency_of_X\" means derivative of X with respect to time. \"troposphere_moles_of_X\" means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe. The chemical formula of molecular hydrogen is H2.", diff --git a/data_descriptors/standard_name/tendency_of_upward_air_velocity.json b/data_descriptors/standard_name/tendency_of_upward_air_velocity.json index 43a49ff09..1ef400408 100644 --- a/data_descriptors/standard_name/tendency_of_upward_air_velocity.json +++ b/data_descriptors/standard_name/tendency_of_upward_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_upward_air_velocity", + "id": "tendency_of_upward_air_velocity", "type": "standard_name", "name": "tendency_of_upward_air_velocity", "description": "\"tendency_of_X\" means derivative of X with respect to time. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector.", diff --git a/data_descriptors/standard_name/tendency_of_upward_air_velocity_due_to_advection.json b/data_descriptors/standard_name/tendency_of_upward_air_velocity_due_to_advection.json index afaef9ab9..e4535ebb5 100644 --- a/data_descriptors/standard_name/tendency_of_upward_air_velocity_due_to_advection.json +++ b/data_descriptors/standard_name/tendency_of_upward_air_velocity_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_upward_air_velocity_due_to_advection", + "id": "tendency_of_upward_air_velocity_due_to_advection", "type": "standard_name", "name": "tendency_of_upward_air_velocity_due_to_advection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector.", diff --git a/data_descriptors/standard_name/tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json b/data_descriptors/standard_name/tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json index 53e13bca5..ff5af74b9 100644 --- a/data_descriptors/standard_name/tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json +++ b/data_descriptors/standard_name/tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", + "id": "tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", "type": "standard_name", "name": "tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", "description": "The phrase \"tendency_of_X\" means derivative of X with respect to time. \"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide. The phrase \"expressed_as\" is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. \"Nitrogen compounds\" summarizes all chemical species containing nitrogen atoms. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. On land, \"nitrogen fixation\" means the uptake of nitrogen gas directly from the atmosphere. The representation of fixed nitrogen is model dependent, with the nitrogen entering either plants, soil or both.", diff --git a/data_descriptors/standard_name/tendency_of_wind_speed_due_to_convection.json b/data_descriptors/standard_name/tendency_of_wind_speed_due_to_convection.json index ce9ac2fe6..341029dd8 100644 --- a/data_descriptors/standard_name/tendency_of_wind_speed_due_to_convection.json +++ b/data_descriptors/standard_name/tendency_of_wind_speed_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_wind_speed_due_to_convection", + "id": "tendency_of_wind_speed_due_to_convection", "type": "standard_name", "name": "tendency_of_wind_speed_due_to_convection", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity.", diff --git a/data_descriptors/standard_name/tendency_of_wind_speed_due_to_gravity_wave_drag.json b/data_descriptors/standard_name/tendency_of_wind_speed_due_to_gravity_wave_drag.json index e77898626..a9d74ffb8 100644 --- a/data_descriptors/standard_name/tendency_of_wind_speed_due_to_gravity_wave_drag.json +++ b/data_descriptors/standard_name/tendency_of_wind_speed_due_to_gravity_wave_drag.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tendency_of_wind_speed_due_to_gravity_wave_drag", + "id": "tendency_of_wind_speed_due_to_gravity_wave_drag", "type": "standard_name", "name": "tendency_of_wind_speed_due_to_gravity_wave_drag", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"tendency_of_X\" means derivative of X with respect to time. Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity.", diff --git a/data_descriptors/standard_name/thermal_conductivity_of_frozen_ground.json b/data_descriptors/standard_name/thermal_conductivity_of_frozen_ground.json index 0e20a3f57..48b89c056 100644 --- a/data_descriptors/standard_name/thermal_conductivity_of_frozen_ground.json +++ b/data_descriptors/standard_name/thermal_conductivity_of_frozen_ground.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thermal_conductivity_of_frozen_ground", + "id": "thermal_conductivity_of_frozen_ground", "type": "standard_name", "name": "thermal_conductivity_of_frozen_ground", "description": "Thermal conductivity is the constant k in the formula q = -k grad T where q is the heat transfer per unit time per unit area of a surface normal to the direction of transfer and grad T is the temperature gradient. Thermal conductivity is a property of the material. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/thermal_energy_content_of_surface_snow.json b/data_descriptors/standard_name/thermal_energy_content_of_surface_snow.json index 287b3070d..6babb1848 100644 --- a/data_descriptors/standard_name/thermal_energy_content_of_surface_snow.json +++ b/data_descriptors/standard_name/thermal_energy_content_of_surface_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thermal_energy_content_of_surface_snow", + "id": "thermal_energy_content_of_surface_snow", "type": "standard_name", "name": "thermal_energy_content_of_surface_snow", "description": "\"Content\" indicates a quantity per unit area. Thermal energy is the total vibrational energy, kinetic and potential, of all the molecules and atoms in a substance. Surface snow refers to the snow on the solid ground or on surface ice cover, but excludes, for example, falling snowflakes and snow on plants.", diff --git a/data_descriptors/standard_name/thermodynamic_phase_of_cloud_water_particles_at_cloud_top.json b/data_descriptors/standard_name/thermodynamic_phase_of_cloud_water_particles_at_cloud_top.json index 56d5fb57f..674bbe871 100644 --- a/data_descriptors/standard_name/thermodynamic_phase_of_cloud_water_particles_at_cloud_top.json +++ b/data_descriptors/standard_name/thermodynamic_phase_of_cloud_water_particles_at_cloud_top.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thermodynamic_phase_of_cloud_water_particles_at_cloud_top", + "id": "thermodynamic_phase_of_cloud_water_particles_at_cloud_top", "type": "standard_name", "name": "thermodynamic_phase_of_cloud_water_particles_at_cloud_top", "description": "A variable with the standard name of thermodynamic_phase_of_cloud_water_particles_at_cloud_top contains integers which can be translated to strings using flag_values and flag_meanings attributes. Alternatively, the data variable may contain strings which indicate the thermodynamic phase. These strings are standardised. Values must be chosen from the following list: liquid; ice; mixed; clear_sky; super_cooled_liquid_water; unknown. \"Water\" means water in all phases. The phrase \"cloud_top\" refers to the top of the highest cloud.", diff --git a/data_descriptors/standard_name/thermosteric_change_in_mean_sea_level.json b/data_descriptors/standard_name/thermosteric_change_in_mean_sea_level.json index 7660ee8d3..5c80a60ba 100644 --- a/data_descriptors/standard_name/thermosteric_change_in_mean_sea_level.json +++ b/data_descriptors/standard_name/thermosteric_change_in_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thermosteric_change_in_mean_sea_level", + "id": "thermosteric_change_in_mean_sea_level", "type": "standard_name", "name": "thermosteric_change_in_mean_sea_level", "description": "Thermosteric sea level change is the part caused by change in sea water density due to change in temperature i.e. thermal expansion. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. Zero mean sea level change is an arbitrary level. The sum of the quantities with standard names thermosteric_change_in_mean_sea_level and halosteric_change_in_mean_sea_level has the standard name steric_change_in_mean_sea_level.", diff --git a/data_descriptors/standard_name/thermosteric_change_in_sea_surface_height.json b/data_descriptors/standard_name/thermosteric_change_in_sea_surface_height.json index d838c6754..a464ccee2 100644 --- a/data_descriptors/standard_name/thermosteric_change_in_sea_surface_height.json +++ b/data_descriptors/standard_name/thermosteric_change_in_sea_surface_height.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thermosteric_change_in_sea_surface_height", + "id": "thermosteric_change_in_sea_surface_height", "type": "standard_name", "name": "thermosteric_change_in_sea_surface_height", "description": "\"Sea surface height\" is a time-varying quantity. The thermosteric change in sea surface height is the change in height that a water column having standard temperature zero degrees Celsius would undergo when its temperature is changed to the observed value. The sum of the quantities with standard names thermosteric_change_in_sea_surface_height and halosteric_change_in_sea_surface_height is the total steric change in the water column height, which has the standard name of steric_change_in_sea_surface_height.", diff --git a/data_descriptors/standard_name/thickness_of_convective_rainfall_amount.json b/data_descriptors/standard_name/thickness_of_convective_rainfall_amount.json index c185f8aa8..b0293a20b 100644 --- a/data_descriptors/standard_name/thickness_of_convective_rainfall_amount.json +++ b/data_descriptors/standard_name/thickness_of_convective_rainfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_convective_rainfall_amount", + "id": "thickness_of_convective_rainfall_amount", "type": "standard_name", "name": "thickness_of_convective_rainfall_amount", "description": "\"Amount\" means mass per unit area. The construction thickness_of_[X_]rainfall_amount means the accumulated \"depth\" of rainfall i.e. the thickness of a layer of liquid water having the same mass per unit area as the rainfall amount.", diff --git a/data_descriptors/standard_name/thickness_of_convective_snowfall_amount.json b/data_descriptors/standard_name/thickness_of_convective_snowfall_amount.json index 017888fcb..fbd69f550 100644 --- a/data_descriptors/standard_name/thickness_of_convective_snowfall_amount.json +++ b/data_descriptors/standard_name/thickness_of_convective_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_convective_snowfall_amount", + "id": "thickness_of_convective_snowfall_amount", "type": "standard_name", "name": "thickness_of_convective_snowfall_amount", "description": "\"Amount\" means mass per unit area. The construction thickness_of_[X_]snowfall_amount means the accumulated \"depth\" of snow which fell i.e. the thickness of the layer of snow at its own density. There are corresponding standard names for liquid water equivalent (lwe) thickness.", diff --git a/data_descriptors/standard_name/thickness_of_ice_on_sea_ice_melt_pond.json b/data_descriptors/standard_name/thickness_of_ice_on_sea_ice_melt_pond.json index d6a43524b..3cd7d9eda 100644 --- a/data_descriptors/standard_name/thickness_of_ice_on_sea_ice_melt_pond.json +++ b/data_descriptors/standard_name/thickness_of_ice_on_sea_ice_melt_pond.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_ice_on_sea_ice_melt_pond", + "id": "thickness_of_ice_on_sea_ice_melt_pond", "type": "standard_name", "name": "thickness_of_ice_on_sea_ice_melt_pond", "description": "\"Thickness\" means the vertical extent of a layer. Melt ponds occur on top of the existing sea ice. The water in melt ponds can refreeze at the surface, giving rise to a layer of ice on the melt pond, which is turn resting on the sea_ice below. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/thickness_of_liquid_water_cloud.json b/data_descriptors/standard_name/thickness_of_liquid_water_cloud.json index db05874e6..269bef649 100644 --- a/data_descriptors/standard_name/thickness_of_liquid_water_cloud.json +++ b/data_descriptors/standard_name/thickness_of_liquid_water_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_liquid_water_cloud", + "id": "thickness_of_liquid_water_cloud", "type": "standard_name", "name": "thickness_of_liquid_water_cloud", "description": "\"Thickness\" means the vertical extent of a layer.", diff --git a/data_descriptors/standard_name/thickness_of_rainfall_amount.json b/data_descriptors/standard_name/thickness_of_rainfall_amount.json index eae4a4432..412822e50 100644 --- a/data_descriptors/standard_name/thickness_of_rainfall_amount.json +++ b/data_descriptors/standard_name/thickness_of_rainfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_rainfall_amount", + "id": "thickness_of_rainfall_amount", "type": "standard_name", "name": "thickness_of_rainfall_amount", "description": "\"Amount\" means mass per unit area. The construction thickness_of_[X_]rainfall_amount means the accumulated \"depth\" of rainfall i.e. the thickness of a layer of liquid water having the same mass per unit area as the rainfall amount.", diff --git a/data_descriptors/standard_name/thickness_of_snowfall_amount.json b/data_descriptors/standard_name/thickness_of_snowfall_amount.json index 75b5d7377..b6451accc 100644 --- a/data_descriptors/standard_name/thickness_of_snowfall_amount.json +++ b/data_descriptors/standard_name/thickness_of_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_snowfall_amount", + "id": "thickness_of_snowfall_amount", "type": "standard_name", "name": "thickness_of_snowfall_amount", "description": "\"Amount\" means mass per unit area. The construction thickness_of_[X_]snowfall_amount means the accumulated \"depth\" of snow which fell i.e. the thickness of the layer of snow at its own density. There are corresponding standard names for liquid water equivalent (lwe) thickness.", diff --git a/data_descriptors/standard_name/thickness_of_soil_surface_organic_layer.json b/data_descriptors/standard_name/thickness_of_soil_surface_organic_layer.json index 757827cdd..f04ba76c4 100644 --- a/data_descriptors/standard_name/thickness_of_soil_surface_organic_layer.json +++ b/data_descriptors/standard_name/thickness_of_soil_surface_organic_layer.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_soil_surface_organic_layer", + "id": "thickness_of_soil_surface_organic_layer", "type": "standard_name", "name": "thickness_of_soil_surface_organic_layer", "description": "Depth or height of the organic soil horizon (O or H horizons per the World Reference Base soil classification system), measured from the soil surface down to the mineral horizon. Organic layers are commonly composed of a succession of litter of recognizable origin, of partly decomposed litter, and of highly decomposed (humic) organic material.", diff --git a/data_descriptors/standard_name/thickness_of_stratiform_rainfall_amount.json b/data_descriptors/standard_name/thickness_of_stratiform_rainfall_amount.json index 50333f714..51f98cc92 100644 --- a/data_descriptors/standard_name/thickness_of_stratiform_rainfall_amount.json +++ b/data_descriptors/standard_name/thickness_of_stratiform_rainfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_stratiform_rainfall_amount", + "id": "thickness_of_stratiform_rainfall_amount", "type": "standard_name", "name": "thickness_of_stratiform_rainfall_amount", "description": "\"Amount\" means mass per unit area. The construction thickness_of_[X_]rainfall_amount means the accumulated \"depth\" of rainfall i.e. the thickness of a layer of liquid water having the same mass per unit area as the rainfall amount. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", diff --git a/data_descriptors/standard_name/thickness_of_stratiform_snowfall_amount.json b/data_descriptors/standard_name/thickness_of_stratiform_snowfall_amount.json index 428a0cab3..0405e0893 100644 --- a/data_descriptors/standard_name/thickness_of_stratiform_snowfall_amount.json +++ b/data_descriptors/standard_name/thickness_of_stratiform_snowfall_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thickness_of_stratiform_snowfall_amount", + "id": "thickness_of_stratiform_snowfall_amount", "type": "standard_name", "name": "thickness_of_stratiform_snowfall_amount", "description": "\"Amount\" means mass per unit area. The construction thickness_of_[X_]snowfall_amount means the accumulated \"depth\" of snow which fell i.e. the thickness of the layer of snow at its own density. There are corresponding standard names for liquid water equivalent (lwe) thickness. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", diff --git a/data_descriptors/standard_name/thunderstorm_probability.json b/data_descriptors/standard_name/thunderstorm_probability.json index 460690f4f..53c7ebc52 100644 --- a/data_descriptors/standard_name/thunderstorm_probability.json +++ b/data_descriptors/standard_name/thunderstorm_probability.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/thunderstorm_probability", + "id": "thunderstorm_probability", "type": "standard_name", "name": "thunderstorm_probability", "description": "\"probability_of_X\" means the chance that X is true or of at least one occurrence of X. Space and time coordinates must be used to indicate the area and time-interval to which a probability applies.", diff --git a/data_descriptors/standard_name/tidal_sea_surface_height_above_lowest_astronomical_tide.json b/data_descriptors/standard_name/tidal_sea_surface_height_above_lowest_astronomical_tide.json index 3ec8ddd87..fb7e22d52 100644 --- a/data_descriptors/standard_name/tidal_sea_surface_height_above_lowest_astronomical_tide.json +++ b/data_descriptors/standard_name/tidal_sea_surface_height_above_lowest_astronomical_tide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tidal_sea_surface_height_above_lowest_astronomical_tide", + "id": "tidal_sea_surface_height_above_lowest_astronomical_tide", "type": "standard_name", "name": "tidal_sea_surface_height_above_lowest_astronomical_tide", "description": "\"Sea surface height\" is a time-varying quantity. \"Height_above_X\" means the vertical distance above the named surface X. \"Lowest astronomical tide\" describes a local vertical reference based on the lowest water level that can be expected to occur under average meteorological conditions and under any combination of astronomical conditions. The tidal component of sea surface height describes the predicted variability of the sea surface due to astronomic forcing (chiefly lunar and solar cycles) and shallow water resonance of tidal components; for example as generated based on harmonic analysis, or resulting from the application of harmonic tidal series as boundary conditions to a numerical tidal model.", diff --git a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_higher_high_water.json b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_higher_high_water.json index de588c25f..0d7446478 100644 --- a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_higher_high_water.json +++ b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_higher_high_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tidal_sea_surface_height_above_mean_higher_high_water", + "id": "tidal_sea_surface_height_above_mean_higher_high_water", "type": "standard_name", "name": "tidal_sea_surface_height_above_mean_higher_high_water", "description": "\"Sea surface height\" is a time-varying quantity. \"Height_above_X\" means the vertical distance above the named surface X. \"Mean higher high water\" is the arithmetic mean of the higher high water height of each tidal day observed at a station over a Tidal Datum Epoch, which is a period of time that is usually greater than 18.6 years to include a full lunar cycle. Tidal datums in certain regions with anomalous sea level changes may be calculated using a shorter, or modified, Tidal Datum Epoch (e.g. 5 years). To specify the tidal datum epoch to which the quantity applies, provide a scalar coordinate variable with standard name reference_epoch.", diff --git a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_low_water_springs.json b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_low_water_springs.json index ad4458e77..36408050c 100644 --- a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_low_water_springs.json +++ b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_low_water_springs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tidal_sea_surface_height_above_mean_low_water_springs", + "id": "tidal_sea_surface_height_above_mean_low_water_springs", "type": "standard_name", "name": "tidal_sea_surface_height_above_mean_low_water_springs", "description": "\"Sea surface height\" is a time-varying quantity. \"Height_above_X\" means the vertical distance above the named surface X. \"Mean low water springs\" describes a local vertical reference based on the time mean of the low water levels during spring tides (the tides each lunar month with the greatest difference between high and low water that happen during full and new moons phases) expected to occur under average meteorological conditions and under any combination of astronomical conditions. The tidal component of sea surface height describes the predicted variability of the sea surface due to astronomic forcing (chiefly lunar and solar cycles) and shallow water resonance of tidal components; for example as generated based on harmonic analysis, or resulting from the application of harmonic tidal series as boundary conditions to a numerical tidal model.", diff --git a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_lower_low_water.json b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_lower_low_water.json index 58593f7dc..361a95b7b 100644 --- a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_lower_low_water.json +++ b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_lower_low_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tidal_sea_surface_height_above_mean_lower_low_water", + "id": "tidal_sea_surface_height_above_mean_lower_low_water", "type": "standard_name", "name": "tidal_sea_surface_height_above_mean_lower_low_water", "description": "\"Sea surface height\" is a time-varying quantity. \"Height_above_X\" means the vertical distance above the named surface X. \"Mean lower low water\" is the arithmetic mean of the lower low water height of each tidal day observed at a station over a Tidal Datum Epoch, which is a period of time that is usually greater than 18.6 years to include a full lunar cycle. Tidal datums in certain regions with anomalous sea level changes may be calculated using a shorter, or modified, Tidal Datum Epoch (e.g. 5 years). To specify the tidal datum epoch to which the quantity applies, provide a scalar coordinate variable with standard name reference_epoch.", diff --git a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_sea_level.json b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_sea_level.json index f0bd83a3e..832e56de2 100644 --- a/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_sea_level.json +++ b/data_descriptors/standard_name/tidal_sea_surface_height_above_mean_sea_level.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tidal_sea_surface_height_above_mean_sea_level", + "id": "tidal_sea_surface_height_above_mean_sea_level", "type": "standard_name", "name": "tidal_sea_surface_height_above_mean_sea_level", "description": "\"Sea surface height\" is a time-varying quantity. \"Height_above_X\" means the vertical distance above the named surface X. \"Mean sea level\" means the time mean of sea surface elevation at a given location over an arbitrary period sufficient to eliminate the tidal signals. The tidal component of sea surface height describes the predicted variability of the sea surface due to astronomic forcing (chiefly lunar and solar cycles) and shallow water resonance of tidal components; for example as generated based on harmonic analysis, or resulting from the application of harmonic tidal series as boundary conditions to a numerical tidal model.", diff --git a/data_descriptors/standard_name/time.json b/data_descriptors/standard_name/time.json index bbea02e1a..b81b5065b 100644 --- a/data_descriptors/standard_name/time.json +++ b/data_descriptors/standard_name/time.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/time", + "id": "time", "type": "standard_name", "name": "time", "description": null, diff --git a/data_descriptors/standard_name/time_of_maximum_flood_depth.json b/data_descriptors/standard_name/time_of_maximum_flood_depth.json index a204c69e8..b17e26e82 100644 --- a/data_descriptors/standard_name/time_of_maximum_flood_depth.json +++ b/data_descriptors/standard_name/time_of_maximum_flood_depth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/time_of_maximum_flood_depth", + "id": "time_of_maximum_flood_depth", "type": "standard_name", "name": "time_of_maximum_flood_depth", "description": "The quantity with standard name time_of_maximum_flood_depth is the time elapsed between the breaking of a levee (origin of flood water simulation) and the instant when the flood depth reaches its maximum during the simulation for a given point in space. Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/time_sample_difference_due_to_collocation.json b/data_descriptors/standard_name/time_sample_difference_due_to_collocation.json index 2b753abc9..fffc2ca0a 100644 --- a/data_descriptors/standard_name/time_sample_difference_due_to_collocation.json +++ b/data_descriptors/standard_name/time_sample_difference_due_to_collocation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/time_sample_difference_due_to_collocation", + "id": "time_sample_difference_due_to_collocation", "type": "standard_name", "name": "time_sample_difference_due_to_collocation", "description": "time_sample_difference_due_to_collocation is the difference in time between two events that are collocated. Two events are deemed to be collocated based on some set of spatial, temporal, and viewing geometry criteria.", diff --git a/data_descriptors/standard_name/time_when_flood_water_falls_below_threshold.json b/data_descriptors/standard_name/time_when_flood_water_falls_below_threshold.json index 3894d87fb..5c34c99f9 100644 --- a/data_descriptors/standard_name/time_when_flood_water_falls_below_threshold.json +++ b/data_descriptors/standard_name/time_when_flood_water_falls_below_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/time_when_flood_water_falls_below_threshold", + "id": "time_when_flood_water_falls_below_threshold", "type": "standard_name", "name": "time_when_flood_water_falls_below_threshold", "description": "The quantity with standard name time_when_flood_water_falls_below_threshold is the time elapsed between the breaking of a levee (origin of flood water simulation) and the instant when the depth falls below a given threshold for the last time, having already risen to its maximum depth, at a given point in space. If a threshold is supplied, it should be specified by associating a coordinate variable or scalar coordinate variable with the data variable and giving the coordinate variable a standard name of flood_water_thickness. The values of the coordinate variable are the threshold values for the corresponding subarrays of the data variable. If no threshold is specified, its value is taken to be zero. Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/time_when_flood_water_rises_above_threshold.json b/data_descriptors/standard_name/time_when_flood_water_rises_above_threshold.json index c540b7915..77f093e12 100644 --- a/data_descriptors/standard_name/time_when_flood_water_rises_above_threshold.json +++ b/data_descriptors/standard_name/time_when_flood_water_rises_above_threshold.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/time_when_flood_water_rises_above_threshold", + "id": "time_when_flood_water_rises_above_threshold", "type": "standard_name", "name": "time_when_flood_water_rises_above_threshold", "description": "The quantity with standard name time_when_flood_water_rises_above_threshold is the time elapsed between the breaking of a levee (origin of flood water simulation) and the instant when the depth first rises above a given threshold at a given point in space. If a threshold is supplied, it should be specified by associating a coordinate variable or scalar coordinate variable with the data variable and giving the coordinate variable a standard name of flood_water_thickness. The values of the coordinate variable are the threshold values for the corresponding subarrays of the data variable. If no threshold is specified, its value is taken to be zero. Flood water is water that covers land which is normally not covered by water.", diff --git a/data_descriptors/standard_name/to_direction_of_air_velocity_relative_to_sea_water.json b/data_descriptors/standard_name/to_direction_of_air_velocity_relative_to_sea_water.json index e91be0aae..caded6287 100644 --- a/data_descriptors/standard_name/to_direction_of_air_velocity_relative_to_sea_water.json +++ b/data_descriptors/standard_name/to_direction_of_air_velocity_relative_to_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/to_direction_of_air_velocity_relative_to_sea_water", + "id": "to_direction_of_air_velocity_relative_to_sea_water", "type": "standard_name", "name": "to_direction_of_air_velocity_relative_to_sea_water", "description": "The quantity with standard name to_direction_of_air_velocity_relative_to_sea_water is the difference between the direction of motion of the air and the near-surface current. The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The components of the relative velocity vector have standard names eastward_air_velocity_relative_to_sea_water and northward_air_velocity_relative_to_sea_water. A vertical coordinate variable or scalar coordinate variable with standard name \"depth\" should be used to indicate the depth of sea water velocity used in the calculation. Similarly, a vertical coordinate variable or scalar coordinate with standard name \"height\" should be used to indicate the height of the the wind component.", diff --git a/data_descriptors/standard_name/to_direction_of_surface_downward_stress.json b/data_descriptors/standard_name/to_direction_of_surface_downward_stress.json index bbccb75ed..0737f2de5 100644 --- a/data_descriptors/standard_name/to_direction_of_surface_downward_stress.json +++ b/data_descriptors/standard_name/to_direction_of_surface_downward_stress.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/to_direction_of_surface_downward_stress", + "id": "to_direction_of_surface_downward_stress", "type": "standard_name", "name": "to_direction_of_surface_downward_stress", "description": "The phrase \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). \"Surface stress\" means the shear stress (force per unit area) exerted by the wind at the surface. A downward stress is a downward flux of momentum. Over large bodies of water, wind stress can drive near-surface currents.", diff --git a/data_descriptors/standard_name/toa_adjusted_longwave_forcing.json b/data_descriptors/standard_name/toa_adjusted_longwave_forcing.json index 31ea892e8..4d985c4ba 100644 --- a/data_descriptors/standard_name/toa_adjusted_longwave_forcing.json +++ b/data_descriptors/standard_name/toa_adjusted_longwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_adjusted_longwave_forcing", + "id": "toa_adjusted_longwave_forcing", "type": "standard_name", "name": "toa_adjusted_longwave_forcing", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_adjusted_radiative_forcing.json b/data_descriptors/standard_name/toa_adjusted_radiative_forcing.json index 866d6c9ac..7d247e5d5 100644 --- a/data_descriptors/standard_name/toa_adjusted_radiative_forcing.json +++ b/data_descriptors/standard_name/toa_adjusted_radiative_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_adjusted_radiative_forcing", + "id": "toa_adjusted_radiative_forcing", "type": "standard_name", "name": "toa_adjusted_radiative_forcing", "description": "The abbreviation \"toa\" means top of atmosphere. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_adjusted_shortwave_forcing.json b/data_descriptors/standard_name/toa_adjusted_shortwave_forcing.json index 2168a9bbe..c2f891411 100644 --- a/data_descriptors/standard_name/toa_adjusted_shortwave_forcing.json +++ b/data_descriptors/standard_name/toa_adjusted_shortwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_adjusted_shortwave_forcing", + "id": "toa_adjusted_shortwave_forcing", "type": "standard_name", "name": "toa_adjusted_shortwave_forcing", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_bidirectional_reflectance.json b/data_descriptors/standard_name/toa_bidirectional_reflectance.json index 2f39c8ea5..ef07e3329 100644 --- a/data_descriptors/standard_name/toa_bidirectional_reflectance.json +++ b/data_descriptors/standard_name/toa_bidirectional_reflectance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_bidirectional_reflectance", + "id": "toa_bidirectional_reflectance", "type": "standard_name", "name": "toa_bidirectional_reflectance", "description": "\"Bidirectional_reflectance\" depends on the angles of incident and measured radiation. Reflectance is the ratio of the energy of the reflected to the incident radiation. A coordinate variable of radiation_wavelength or radiation_frequency can be used to specify the wavelength or frequency, respectively, of the radiation. \"toa\" means top of atmosphere. toa_bidirectional_reflectance includes a factor to account for the cosine of the solar zenith angle but does not include any integration over solid angle.", diff --git a/data_descriptors/standard_name/toa_brightness_temperature.json b/data_descriptors/standard_name/toa_brightness_temperature.json index 4278ed66e..f2c09fcec 100644 --- a/data_descriptors/standard_name/toa_brightness_temperature.json +++ b/data_descriptors/standard_name/toa_brightness_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_brightness_temperature", + "id": "toa_brightness_temperature", "type": "standard_name", "name": "toa_brightness_temperature", "description": "The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. \"toa\" means top of atmosphere. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/toa_brightness_temperature_assuming_clear_sky.json b/data_descriptors/standard_name/toa_brightness_temperature_assuming_clear_sky.json index e966eacba..e022de68e 100644 --- a/data_descriptors/standard_name/toa_brightness_temperature_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_brightness_temperature_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_brightness_temperature_assuming_clear_sky", + "id": "toa_brightness_temperature_assuming_clear_sky", "type": "standard_name", "name": "toa_brightness_temperature_assuming_clear_sky", "description": "The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"toa\" means top of atmosphere. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration.json b/data_descriptors/standard_name/toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration.json index 68a2189f6..2c1ddbfad 100644 --- a/data_descriptors/standard_name/toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration.json +++ b/data_descriptors/standard_name/toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration", + "id": "toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration", "type": "standard_name", "name": "toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration", "description": "toa_brightness_temperature_bias_at_standard_scene_due_to_intercalibration is the difference between top-of-atmosphere (TOA) brightness temperature of the reference sensor and TOA brightness temperature of the monitored sensor. This TOA brightness temperature difference is a measure of the calibration difference between the monitored and reference sensors. The standard scene is a target area with typical Earth surface and atmospheric conditions that is accepted as a reference. Brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area at a given wavenumber. TOA brightness temperature of the standard scene is calculated using a radiative transfer simulation for a given viewing geometry. The resultant top-of-atmosphere spectral radiance is then integrated with each sensor's spectral response function and converted to equivalent brightness temperature. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. It is strongly recommended that a variable with this standard name should have the attribute units_metadata=\"temperature: difference\", meaning that it refers to temperature differences and implying that the origin of the temperature scale is irrelevant, because it is essential to know whether a temperature is on-scale or a difference in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/toa_brightness_temperature_of_standard_scene.json b/data_descriptors/standard_name/toa_brightness_temperature_of_standard_scene.json index be1396f25..6b254569c 100644 --- a/data_descriptors/standard_name/toa_brightness_temperature_of_standard_scene.json +++ b/data_descriptors/standard_name/toa_brightness_temperature_of_standard_scene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_brightness_temperature_of_standard_scene", + "id": "toa_brightness_temperature_of_standard_scene", "type": "standard_name", "name": "toa_brightness_temperature_of_standard_scene", "description": "\"toa\" means top of atmosphere. The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area at a given wavenumber. The standard scene is a target area with typical Earth surface and atmospheric conditions that is accepted as a reference. The toa radiance of the standard scene is calculated using a radiative transfer model for a given viewing geometry. The resultant toa spectral radiance is then integrated with a sensor's spectral response function and converted to equivalent brightness temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/toa_cloud_radiative_effect.json b/data_descriptors/standard_name/toa_cloud_radiative_effect.json index 06ff77877..97987e362 100644 --- a/data_descriptors/standard_name/toa_cloud_radiative_effect.json +++ b/data_descriptors/standard_name/toa_cloud_radiative_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_cloud_radiative_effect", + "id": "toa_cloud_radiative_effect", "type": "standard_name", "name": "toa_cloud_radiative_effect", "description": "The abbreviation \"toa\" means top of atmosphere. Cloud radiative effect is also commonly known as \"cloud radiative forcing\". It is the sum of the quantities with standard names toa_shortwave_cloud_radiative_effect and toa_longwave_cloud_radiative_effect. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_incoming_shortwave_flux.json b/data_descriptors/standard_name/toa_incoming_shortwave_flux.json index 148b6caf5..9153ff445 100644 --- a/data_descriptors/standard_name/toa_incoming_shortwave_flux.json +++ b/data_descriptors/standard_name/toa_incoming_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_incoming_shortwave_flux", + "id": "toa_incoming_shortwave_flux", "type": "standard_name", "name": "toa_incoming_shortwave_flux", "description": "\"shortwave\" means shortwave radiation. \"toa\" means top of atmosphere. The TOA incoming shortwave flux is the radiative flux from the sun i.e. the \"downwelling\" TOA shortwave flux. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_instantaneous_longwave_forcing.json b/data_descriptors/standard_name/toa_instantaneous_longwave_forcing.json index 409797adc..10001527a 100644 --- a/data_descriptors/standard_name/toa_instantaneous_longwave_forcing.json +++ b/data_descriptors/standard_name/toa_instantaneous_longwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_instantaneous_longwave_forcing", + "id": "toa_instantaneous_longwave_forcing", "type": "standard_name", "name": "toa_instantaneous_longwave_forcing", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.). A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_instantaneous_radiative_forcing.json b/data_descriptors/standard_name/toa_instantaneous_radiative_forcing.json index 9ed103063..d76084fa2 100644 --- a/data_descriptors/standard_name/toa_instantaneous_radiative_forcing.json +++ b/data_descriptors/standard_name/toa_instantaneous_radiative_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_instantaneous_radiative_forcing", + "id": "toa_instantaneous_radiative_forcing", "type": "standard_name", "name": "toa_instantaneous_radiative_forcing", "description": "The abbreviation \"toa\" means top of atmosphere. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.). A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_instantaneous_shortwave_forcing.json b/data_descriptors/standard_name/toa_instantaneous_shortwave_forcing.json index f3f546316..926e159bf 100644 --- a/data_descriptors/standard_name/toa_instantaneous_shortwave_forcing.json +++ b/data_descriptors/standard_name/toa_instantaneous_shortwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_instantaneous_shortwave_forcing", + "id": "toa_instantaneous_shortwave_forcing", "type": "standard_name", "name": "toa_instantaneous_shortwave_forcing", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.). A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/toa_longwave_cloud_radiative_effect.json b/data_descriptors/standard_name/toa_longwave_cloud_radiative_effect.json index 374ef5b8d..893b078dc 100644 --- a/data_descriptors/standard_name/toa_longwave_cloud_radiative_effect.json +++ b/data_descriptors/standard_name/toa_longwave_cloud_radiative_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_longwave_cloud_radiative_effect", + "id": "toa_longwave_cloud_radiative_effect", "type": "standard_name", "name": "toa_longwave_cloud_radiative_effect", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. Cloud radiative effect is also commonly known as \"cloud radiative forcing\". It is the difference in radiative flux resulting from the presence of clouds. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system. The quantity with standard name toa_longwave_cloud_radiative_effect is the difference between those with standard names toa_outgoing_longwave_flux_assuming_clear_sky and toa_outgoing_longwave_flux.", diff --git a/data_descriptors/standard_name/toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json b/data_descriptors/standard_name/toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json index 76136f4c5..e12838fc5 100644 --- a/data_descriptors/standard_name/toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", + "id": "toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "type": "standard_name", "name": "toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "description": "\"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. \"X_direct_radiative_effect\" refers to the instantaneous radiative impact of X on the Earth's energy balance, excluding secondary effects such as changes in cloud cover which may be caused by X. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/toa_net_downward_longwave_flux.json b/data_descriptors/standard_name/toa_net_downward_longwave_flux.json index 43b7c5720..871e2a805 100644 --- a/data_descriptors/standard_name/toa_net_downward_longwave_flux.json +++ b/data_descriptors/standard_name/toa_net_downward_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_downward_longwave_flux", + "id": "toa_net_downward_longwave_flux", "type": "standard_name", "name": "toa_net_downward_longwave_flux", "description": "\"longwave\" means longwave radiation. \"toa\" means top of atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_downward_longwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/toa_net_downward_longwave_flux_assuming_clear_sky.json index 4085d4c19..aa61f64f6 100644 --- a/data_descriptors/standard_name/toa_net_downward_longwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_net_downward_longwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_downward_longwave_flux_assuming_clear_sky", + "id": "toa_net_downward_longwave_flux_assuming_clear_sky", "type": "standard_name", "name": "toa_net_downward_longwave_flux_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"toa\" means top of atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_downward_radiative_flux.json b/data_descriptors/standard_name/toa_net_downward_radiative_flux.json index e6303df5b..5ea12f322 100644 --- a/data_descriptors/standard_name/toa_net_downward_radiative_flux.json +++ b/data_descriptors/standard_name/toa_net_downward_radiative_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_downward_radiative_flux", + "id": "toa_net_downward_radiative_flux", "type": "standard_name", "name": "toa_net_downward_radiative_flux", "description": "\"toa\" means top of atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_downward_shortwave_flux.json b/data_descriptors/standard_name/toa_net_downward_shortwave_flux.json index df344fd0a..f8afb0b69 100644 --- a/data_descriptors/standard_name/toa_net_downward_shortwave_flux.json +++ b/data_descriptors/standard_name/toa_net_downward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_downward_shortwave_flux", + "id": "toa_net_downward_shortwave_flux", "type": "standard_name", "name": "toa_net_downward_shortwave_flux", "description": "\"shortwave\" means shortwave radiation. \"toa\" means top of atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_downward_shortwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/toa_net_downward_shortwave_flux_assuming_clear_sky.json index 549afcd30..3443da44a 100644 --- a/data_descriptors/standard_name/toa_net_downward_shortwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_net_downward_shortwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_downward_shortwave_flux_assuming_clear_sky", + "id": "toa_net_downward_shortwave_flux_assuming_clear_sky", "type": "standard_name", "name": "toa_net_downward_shortwave_flux_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"shortwave\" means shortwave radiation. \"toa\" means top of atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_upward_longwave_flux.json b/data_descriptors/standard_name/toa_net_upward_longwave_flux.json index 7fec767ae..09fc9976f 100644 --- a/data_descriptors/standard_name/toa_net_upward_longwave_flux.json +++ b/data_descriptors/standard_name/toa_net_upward_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_upward_longwave_flux", + "id": "toa_net_upward_longwave_flux", "type": "standard_name", "name": "toa_net_upward_longwave_flux", "description": "\"longwave\" means longwave radiation. \"toa\" means top of atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_upward_longwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/toa_net_upward_longwave_flux_assuming_clear_sky.json index ad8c957b5..40b85f34d 100644 --- a/data_descriptors/standard_name/toa_net_upward_longwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_net_upward_longwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_upward_longwave_flux_assuming_clear_sky", + "id": "toa_net_upward_longwave_flux_assuming_clear_sky", "type": "standard_name", "name": "toa_net_upward_longwave_flux_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"toa\" means top of atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_net_upward_shortwave_flux.json b/data_descriptors/standard_name/toa_net_upward_shortwave_flux.json index ad7557476..592f83705 100644 --- a/data_descriptors/standard_name/toa_net_upward_shortwave_flux.json +++ b/data_descriptors/standard_name/toa_net_upward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_net_upward_shortwave_flux", + "id": "toa_net_upward_shortwave_flux", "type": "standard_name", "name": "toa_net_upward_shortwave_flux", "description": "\"shortwave\" means shortwave radiation. \"toa\" means top of atmosphere. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux.json index 23704f2af..3061e050a 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux", + "id": "toa_outgoing_longwave_flux", "type": "standard_name", "name": "toa_outgoing_longwave_flux", "description": "\"longwave\" means longwave radiation. \"toa\" means top of atmosphere. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky.json index fa2afa4e9..7e52841d4 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux_assuming_clear_sky", + "id": "toa_outgoing_longwave_flux_assuming_clear_sky", "type": "standard_name", "name": "toa_outgoing_longwave_flux_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"toa\" means top of atmosphere. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json index e6a6c6d4a..aa2d36f2e 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air", + "id": "toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 213d2c138..596495880 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "toa_outgoing_longwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"toa\" means top of atmosphere. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json index 7698ec7a0..1801a7e49 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air", + "id": "toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_methane_in_air", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json index 681f7aa24..459a846ac 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "toa_outgoing_longwave_flux_assuming_reference_mole_fraction_of_ozone_in_air", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"longwave\" means longwave radiation. \"toa\" means top of atmosphere. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json b/data_descriptors/standard_name/toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json index 0989d30b0..80a7c6869 100644 --- a/data_descriptors/standard_name/toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", + "id": "toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", "type": "standard_name", "name": "toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", "description": "\"toa\" means top of atmosphere. The term \"longwave\" means longwave radiation. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the \"outgoing longwave radiation\" or \"OLR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength.json index 803aaa931..e599c796d 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavelength", + "id": "toa_outgoing_radiance_per_unit_wavelength", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavelength", "description": "\"toa\" means top of atmosphere. The TOA outgoing radiance is the upwelling radiance, i.e., toward outer space. Radiance is the radiative flux in a particular direction, per unit of solid angle. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence.json index d7d4b06a1..1d01208d7 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence", + "id": "toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavelength_due_to_solar_induced_fluorescence", "description": "The abbreviation \"toa\" means top of atmosphere. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Some of the solar energy absorbed by pigment systems of plant leaves during photosynthesis is re-emitted as fluorescence. This is called solar-induced chlorophyll fluorescence (SIF). It is a radiance that can be measured on a global scale at various wavelengths and by multiple space borne instruments. SIF is considered a measurement of the photosynthetic machinery in plants and can provide a direct approach for the diagnosis of the actual functional status of vegetation. It is therefore considered a functional proxy of terrestrial gross primary productivity which has the standard name gross_primary_productivity_of_biomass_expressed_as_carbon. SIF spans the wavelength range 600 - 800 nm.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber.json index 5729a534c..41550fd7b 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavenumber", + "id": "toa_outgoing_radiance_per_unit_wavenumber", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavenumber", "description": "\"toa\" means top of atmosphere. The TOA outgoing radiance is the upwelling radiance, i.e., toward outer space. Radiance is the radiative flux in a particular direction, per unit of solid angle. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene.json index 8710c41af..13a29ec8f 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene", + "id": "toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene", "description": "toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_scene is an average of observations of the quantity with standard name toa_outgoing_radiance_per_unit_wavenumber from a sensor's adjacent field-of-views within a collocation scene. \"toa\" means top of atmosphere. The TOA outgoing radiance is the upwelling radiance, i.e., toward outer space. Radiance is the radiative flux in a particular direction, per unit of solid angle. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The \"collocation scene\" is a grouping of a sensor's adjacent field-of-views centered on a collocation target. The size of the collocation scene is typically about twice that of the collocation target. The \"collocation target\" is an area on the Earth's surface at which observations from at least two sensors are collected. Its size is defined by the sensor with the largest field-of-view footprint. Two events are deemed to be collocated based on some set of spatial, temporal, and viewing geometry criteria.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target.json index 49a24512e..b5b8e1029 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target", + "id": "toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target", "description": "toa_outgoing_radiance_per_unit_wavenumber_mean_within_collocation_target is an average of observations of the quantity with standard name toa_outgoing_radiance_per_unit_wavenumber from a sensor's adjacent field-of-views within a collocation target. \"toa\" means top of atmosphere. The TOA outgoing radiance is the upwelling radiance, i.e., toward outer space. Radiance is the radiative flux in a particular direction, per unit of solid angle. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The \"collocation target\" is an area on the Earth's surface at which observations from at least two sensors are collected. Its size is defined by the sensor with the largest field-of-view footprint. Two events are deemed to be collocated based on some set of spatial, temporal, and viewing geometry criteria.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene.json index 303471551..3595637fe 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene", + "id": "toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene", "description": "toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_scene is the standard deviation of observations of the quantity with standard name toa_outgoing_radiance_per_unit_wavenumber from a sensor's adjacent field-of-views within a collocation scene. \"toa\" means top of atmosphere. The TOA outgoing radiance is the upwelling radiance, i.e., toward outer space. Radiance is the radiative flux in a particular direction, per unit of solid angle. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The \"collocation scene\" is a grouping of a sensor's adjacent field-of-views centered on a collocation target. The size of the collocation scene is typically about twice that of the collocation target. The \"collocation target\" is an area on the Earth's surface at which observations from at least two sensors are collected. Its size is defined by the sensor with the largest field-of-view footprint. Two events are deemed to be collocated based on some set of spatial, temporal, and viewing geometry criteria.", diff --git a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target.json b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target.json index 0a96b230e..7bce9a032 100644 --- a/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target.json +++ b/data_descriptors/standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target", + "id": "toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target", "type": "standard_name", "name": "toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target", "description": "toa_outgoing_radiance_per_unit_wavenumber_stdev_within_collocation_target is the standard deviation of observations of the quantity with standard name toa_outgoing_radiance_per_unit_wavenumber from a sensor's adjacent field-of-views within a collocation target. \"toa\" means top of atmosphere. The TOA outgoing radiance is the upwelling radiance, i.e., toward outer space. Radiance is the radiative flux in a particular direction, per unit of solid angle. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The \"collocation target\" is an area on the Earth's surface at which observations from at least two sensors are collected. Its size is defined by the sensor with the largest field-of-view footprint. Two events are deemed to be collocated based on some set of spatial, temporal, and viewing geometry criteria.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux.json index 952672430..2ce6c8922 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux", + "id": "toa_outgoing_shortwave_flux", "type": "standard_name", "name": "toa_outgoing_shortwave_flux", "description": "\"shortwave\" means shortwave radiation. \"toa\" means top of atmosphere. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky.json index 127ac8523..84fefefdc 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky", + "id": "toa_outgoing_shortwave_flux_assuming_clear_sky", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "description": "A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"shortwave\" means shortwave radiation. \"toa\" means top of atmosphere. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol.json index 41b432b18..641ab36b5 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol", + "id": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json index be7e83983..0cd0ad465 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air", + "id": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_methane_in_air", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 9d08ef2e9..9fa52f746 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_no_aerosol.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_no_aerosol.json index 3ef7030ab..d26910d11 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_no_aerosol.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_no_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_no_aerosol", + "id": "toa_outgoing_shortwave_flux_assuming_no_aerosol", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_no_aerosol", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json index d96abeb67..a712368d5 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air", + "id": "toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_methane_in_air", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. The chemical formula for methane is CH4.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json index b0280f802..34d0abab3 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_assuming_reference_mole_fraction_of_ozone_in_air", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json index 8059d23a5..49dd6ff31 100644 --- a/data_descriptors/standard_name/toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json +++ b/data_descriptors/standard_name/toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", + "id": "toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", "type": "standard_name", "name": "toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the \"upwelling\" TOA shortwave flux, sometimes called the \"outgoing shortwave radiation\" or \"OSR\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\". Volcanic aerosols include both volcanic ash and secondary products such as sulphate aerosols formed from gaseous emissions of volcanic eruptions. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.", diff --git a/data_descriptors/standard_name/toa_shortwave_cloud_radiative_effect.json b/data_descriptors/standard_name/toa_shortwave_cloud_radiative_effect.json index 1fd3e9541..6e4089906 100644 --- a/data_descriptors/standard_name/toa_shortwave_cloud_radiative_effect.json +++ b/data_descriptors/standard_name/toa_shortwave_cloud_radiative_effect.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/toa_shortwave_cloud_radiative_effect", + "id": "toa_shortwave_cloud_radiative_effect", "type": "standard_name", "name": "toa_shortwave_cloud_radiative_effect", "description": "The abbreviation \"toa\" means top of atmosphere. The term \"shortwave\" means shortwave radiation. Cloud radiative effect is also commonly known as \"cloud radiative forcing\". It is the difference in radiative flux resulting from the presence of clouds. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system. The quantity with standard name toa_shortwave_cloud_radiative_effect is the difference between those with standard names toa_net_downward_shortwave_flux and toa_net_downward_shortwave_flux_assuming_clear_sky.", diff --git a/data_descriptors/standard_name/tracer_lifetime.json b/data_descriptors/standard_name/tracer_lifetime.json index 5e236881c..64dc7056b 100644 --- a/data_descriptors/standard_name/tracer_lifetime.json +++ b/data_descriptors/standard_name/tracer_lifetime.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tracer_lifetime", + "id": "tracer_lifetime", "type": "standard_name", "name": "tracer_lifetime", "description": "The quantity with standard name tracer_lifetime is the total length of time a passive tracer exists within a medium. Passive tracers are used in models to study processes such as transport and deposition.", diff --git a/data_descriptors/standard_name/transpiration_amount.json b/data_descriptors/standard_name/transpiration_amount.json index 8285065b7..3c6f890a7 100644 --- a/data_descriptors/standard_name/transpiration_amount.json +++ b/data_descriptors/standard_name/transpiration_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/transpiration_amount", + "id": "transpiration_amount", "type": "standard_name", "name": "transpiration_amount", "description": "\"Amount\" means mass per unit area. Transpiration is the process by which liquid water in plant stomata is transferred as water vapor into the atmosphere.", diff --git a/data_descriptors/standard_name/transpiration_flux.json b/data_descriptors/standard_name/transpiration_flux.json index 8f76b3991..a19f41e59 100644 --- a/data_descriptors/standard_name/transpiration_flux.json +++ b/data_descriptors/standard_name/transpiration_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/transpiration_flux", + "id": "transpiration_flux", "type": "standard_name", "name": "transpiration_flux", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Transpiration is the process by which liquid water in plant stomata is transferred as water vapor into the atmosphere.", diff --git a/data_descriptors/standard_name/tropical_cyclone_eye_brightness_temperature.json b/data_descriptors/standard_name/tropical_cyclone_eye_brightness_temperature.json index 3ccf6f8d2..bff56f131 100644 --- a/data_descriptors/standard_name/tropical_cyclone_eye_brightness_temperature.json +++ b/data_descriptors/standard_name/tropical_cyclone_eye_brightness_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropical_cyclone_eye_brightness_temperature", + "id": "tropical_cyclone_eye_brightness_temperature", "type": "standard_name", "name": "tropical_cyclone_eye_brightness_temperature", "description": "The quantity with standard name tropical_cyclone_eye_brightness_temperature is the warmest brightness temperature value in the eye region of a tropical cyclone (0 - 24 km from the storm center) derived using the Advanced Dvorak Technique, based on satellite observations. Reference: Olander, T. L., & Velden, C. S., The Advanced Dvorak Technique: Continued Development of an Objective Scheme to Estimate Tropical Cyclone Intensity Using Geostationary Infrared Satellite Imagery (2007). American Meteorological Society Weather and Forecasting, 22, 287-298. The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tropical_cyclone_maximum_sustained_wind_speed.json b/data_descriptors/standard_name/tropical_cyclone_maximum_sustained_wind_speed.json index c2e51bcb0..46342cca0 100644 --- a/data_descriptors/standard_name/tropical_cyclone_maximum_sustained_wind_speed.json +++ b/data_descriptors/standard_name/tropical_cyclone_maximum_sustained_wind_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropical_cyclone_maximum_sustained_wind_speed", + "id": "tropical_cyclone_maximum_sustained_wind_speed", "type": "standard_name", "name": "tropical_cyclone_maximum_sustained_wind_speed", "description": "The quantity with standard name tropical_cyclone_maximum_sustained_wind_speed is the maximum sustained wind speed of a tropical cyclone, sustained over a period of one minute at the surface of the earth, derived using the Advanced Dvorak Technique based on satellite observations. Reference: Olander, T. L., & Velden, C. S., The Advanced Dvorak Technique: Continued Development of an Objective Scheme to Estimate Tropical Cyclone Intensity Using Geostationary Infrared Satellite Imagery (2007). American Meteorological Society Weather and Forecasting, 22, 287-298.", diff --git a/data_descriptors/standard_name/tropopause_adjusted_longwave_forcing.json b/data_descriptors/standard_name/tropopause_adjusted_longwave_forcing.json index 84087c11c..1fb699996 100644 --- a/data_descriptors/standard_name/tropopause_adjusted_longwave_forcing.json +++ b/data_descriptors/standard_name/tropopause_adjusted_longwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_adjusted_longwave_forcing", + "id": "tropopause_adjusted_longwave_forcing", "type": "standard_name", "name": "tropopause_adjusted_longwave_forcing", "description": "The term \"longwave\" means longwave radiation. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/tropopause_adjusted_radiative_forcing.json b/data_descriptors/standard_name/tropopause_adjusted_radiative_forcing.json index 724caeda2..83dbc38d0 100644 --- a/data_descriptors/standard_name/tropopause_adjusted_radiative_forcing.json +++ b/data_descriptors/standard_name/tropopause_adjusted_radiative_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_adjusted_radiative_forcing", + "id": "tropopause_adjusted_radiative_forcing", "type": "standard_name", "name": "tropopause_adjusted_radiative_forcing", "description": "Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/tropopause_adjusted_shortwave_forcing.json b/data_descriptors/standard_name/tropopause_adjusted_shortwave_forcing.json index 4ed9a3b1c..6f95bab58 100644 --- a/data_descriptors/standard_name/tropopause_adjusted_shortwave_forcing.json +++ b/data_descriptors/standard_name/tropopause_adjusted_shortwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_adjusted_shortwave_forcing", + "id": "tropopause_adjusted_shortwave_forcing", "type": "standard_name", "name": "tropopause_adjusted_shortwave_forcing", "description": "The term \"shortwave\" means shortwave radiation. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment. A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/tropopause_air_pressure.json b/data_descriptors/standard_name/tropopause_air_pressure.json index c0ea3616d..df6a6bbc8 100644 --- a/data_descriptors/standard_name/tropopause_air_pressure.json +++ b/data_descriptors/standard_name/tropopause_air_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_air_pressure", + "id": "tropopause_air_pressure", "type": "standard_name", "name": "tropopause_air_pressure", "description": "Air pressure is the force per unit area which would be exerted when the moving gas molecules of which the air is composed strike a theoretical surface of any orientation.", diff --git a/data_descriptors/standard_name/tropopause_air_temperature.json b/data_descriptors/standard_name/tropopause_air_temperature.json index 0abb6122a..5cadc76b6 100644 --- a/data_descriptors/standard_name/tropopause_air_temperature.json +++ b/data_descriptors/standard_name/tropopause_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_air_temperature", + "id": "tropopause_air_temperature", "type": "standard_name", "name": "tropopause_air_temperature", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/tropopause_altitude.json b/data_descriptors/standard_name/tropopause_altitude.json index f98f69a53..cc30c49be 100644 --- a/data_descriptors/standard_name/tropopause_altitude.json +++ b/data_descriptors/standard_name/tropopause_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_altitude", + "id": "tropopause_altitude", "type": "standard_name", "name": "tropopause_altitude", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", diff --git a/data_descriptors/standard_name/tropopause_downwelling_longwave_flux.json b/data_descriptors/standard_name/tropopause_downwelling_longwave_flux.json index d8e67490e..e2dafaa69 100644 --- a/data_descriptors/standard_name/tropopause_downwelling_longwave_flux.json +++ b/data_descriptors/standard_name/tropopause_downwelling_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_downwelling_longwave_flux", + "id": "tropopause_downwelling_longwave_flux", "type": "standard_name", "name": "tropopause_downwelling_longwave_flux", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"longwave\" means longwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/tropopause_instantaneous_longwave_forcing.json b/data_descriptors/standard_name/tropopause_instantaneous_longwave_forcing.json index fd87d3a88..0e768f953 100644 --- a/data_descriptors/standard_name/tropopause_instantaneous_longwave_forcing.json +++ b/data_descriptors/standard_name/tropopause_instantaneous_longwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_instantaneous_longwave_forcing", + "id": "tropopause_instantaneous_longwave_forcing", "type": "standard_name", "name": "tropopause_instantaneous_longwave_forcing", "description": "The term \"longwave\" means longwave radiation. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.). A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/tropopause_instantaneous_radiative_forcing.json b/data_descriptors/standard_name/tropopause_instantaneous_radiative_forcing.json index 77cb5ff25..42cc119bd 100644 --- a/data_descriptors/standard_name/tropopause_instantaneous_radiative_forcing.json +++ b/data_descriptors/standard_name/tropopause_instantaneous_radiative_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_instantaneous_radiative_forcing", + "id": "tropopause_instantaneous_radiative_forcing", "type": "standard_name", "name": "tropopause_instantaneous_radiative_forcing", "description": "Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.). A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/tropopause_instantaneous_shortwave_forcing.json b/data_descriptors/standard_name/tropopause_instantaneous_shortwave_forcing.json index 89da1fc98..f326c0c93 100644 --- a/data_descriptors/standard_name/tropopause_instantaneous_shortwave_forcing.json +++ b/data_descriptors/standard_name/tropopause_instantaneous_shortwave_forcing.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_instantaneous_shortwave_forcing", + "id": "tropopause_instantaneous_shortwave_forcing", "type": "standard_name", "name": "tropopause_instantaneous_shortwave_forcing", "description": "The term \"shortwave\" means shortwave radiation. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.). A positive radiative forcing or radiative effect is equivalent to a downward radiative flux and contributes to a warming of the earth system.", diff --git a/data_descriptors/standard_name/tropopause_net_downward_longwave_flux.json b/data_descriptors/standard_name/tropopause_net_downward_longwave_flux.json index f0e6ac29a..1c4b7cd9a 100644 --- a/data_descriptors/standard_name/tropopause_net_downward_longwave_flux.json +++ b/data_descriptors/standard_name/tropopause_net_downward_longwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_net_downward_longwave_flux", + "id": "tropopause_net_downward_longwave_flux", "type": "standard_name", "name": "tropopause_net_downward_longwave_flux", "description": "\"longwave\" means longwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/tropopause_net_downward_shortwave_flux.json b/data_descriptors/standard_name/tropopause_net_downward_shortwave_flux.json index f091afd66..0de7f4c56 100644 --- a/data_descriptors/standard_name/tropopause_net_downward_shortwave_flux.json +++ b/data_descriptors/standard_name/tropopause_net_downward_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_net_downward_shortwave_flux", + "id": "tropopause_net_downward_shortwave_flux", "type": "standard_name", "name": "tropopause_net_downward_shortwave_flux", "description": "\"shortwave\" means shortwave radiation. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/tropopause_upwelling_shortwave_flux.json b/data_descriptors/standard_name/tropopause_upwelling_shortwave_flux.json index bb9e43a8f..bc5eceb05 100644 --- a/data_descriptors/standard_name/tropopause_upwelling_shortwave_flux.json +++ b/data_descriptors/standard_name/tropopause_upwelling_shortwave_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/tropopause_upwelling_shortwave_flux", + "id": "tropopause_upwelling_shortwave_flux", "type": "standard_name", "name": "tropopause_upwelling_shortwave_flux", "description": "The term \"shortwave\" means shortwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_bromine_monoxide.json b/data_descriptors/standard_name/troposphere_mole_content_of_bromine_monoxide.json index 03c7db9dc..8d6fd0b43 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_bromine_monoxide.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_bromine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_bromine_monoxide", + "id": "troposphere_mole_content_of_bromine_monoxide", "type": "standard_name", "name": "troposphere_mole_content_of_bromine_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for bromine_monoxide is BrO.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_formaldehyde.json b/data_descriptors/standard_name/troposphere_mole_content_of_formaldehyde.json index 2689a9f16..87d06f0b4 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_formaldehyde.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_formaldehyde.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_formaldehyde", + "id": "troposphere_mole_content_of_formaldehyde", "type": "standard_name", "name": "troposphere_mole_content_of_formaldehyde", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for formaldehyde is CH2O. The IUPAC name for formaldehyde is methanal.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_glyoxal.json b/data_descriptors/standard_name/troposphere_mole_content_of_glyoxal.json index e00d6bcff..7a6aee758 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_glyoxal.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_glyoxal.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_glyoxal", + "id": "troposphere_mole_content_of_glyoxal", "type": "standard_name", "name": "troposphere_mole_content_of_glyoxal", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for glyoxal is CHOCHO. The IUPAC name for glyoxal is ethanedial.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_iodine_monoxide.json b/data_descriptors/standard_name/troposphere_mole_content_of_iodine_monoxide.json index fd63613cd..301f2248f 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_iodine_monoxide.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_iodine_monoxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_iodine_monoxide", + "id": "troposphere_mole_content_of_iodine_monoxide", "type": "standard_name", "name": "troposphere_mole_content_of_iodine_monoxide", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for iodine_monoxide is IO.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_nitrogen_dioxide.json b/data_descriptors/standard_name/troposphere_mole_content_of_nitrogen_dioxide.json index e98a86f76..dc01ee5ce 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_nitrogen_dioxide.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_nitrogen_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_nitrogen_dioxide", + "id": "troposphere_mole_content_of_nitrogen_dioxide", "type": "standard_name", "name": "troposphere_mole_content_of_nitrogen_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for nitrogen_dioxide is NO2.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_ozone.json b/data_descriptors/standard_name/troposphere_mole_content_of_ozone.json index 2d59069f8..5b1a15253 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_ozone.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_ozone.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_ozone", + "id": "troposphere_mole_content_of_ozone", "type": "standard_name", "name": "troposphere_mole_content_of_ozone", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The chemical formula for ozone is O3. The IUPAC name for ozone is trioxygen.", diff --git a/data_descriptors/standard_name/troposphere_mole_content_of_sulfur_dioxide.json b/data_descriptors/standard_name/troposphere_mole_content_of_sulfur_dioxide.json index bc8bd188d..320cf28a9 100644 --- a/data_descriptors/standard_name/troposphere_mole_content_of_sulfur_dioxide.json +++ b/data_descriptors/standard_name/troposphere_mole_content_of_sulfur_dioxide.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/troposphere_mole_content_of_sulfur_dioxide", + "id": "troposphere_mole_content_of_sulfur_dioxide", "type": "standard_name", "name": "troposphere_mole_content_of_sulfur_dioxide", "description": "\"Content\" indicates a quantity per unit area. The \"troposphere content\" of a quantity refers to the vertical integral from the surface to the tropopause. For the content between specified levels in the atmosphere, standard names including \"content_of_atmosphere_layer\" are used. The chemical formula for sulfur dioxide is SO2.", diff --git a/data_descriptors/standard_name/turbulent_mixing_length_of_sea_water.json b/data_descriptors/standard_name/turbulent_mixing_length_of_sea_water.json index 568775ed8..6a57c35a1 100644 --- a/data_descriptors/standard_name/turbulent_mixing_length_of_sea_water.json +++ b/data_descriptors/standard_name/turbulent_mixing_length_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/turbulent_mixing_length_of_sea_water", + "id": "turbulent_mixing_length_of_sea_water", "type": "standard_name", "name": "turbulent_mixing_length_of_sea_water", "description": "\"Turbulent mixing length\" is used in models to describe the average distance over which a fluid parcel can travel while retaining properties that allow the parcel to be distinguished from its immediate environment. \"Turbulent mixing\" means chaotic fluctuations of the fluid flow.", diff --git a/data_descriptors/standard_name/ultraviolet_index.json b/data_descriptors/standard_name/ultraviolet_index.json index 0a9b3651f..530b68e2a 100644 --- a/data_descriptors/standard_name/ultraviolet_index.json +++ b/data_descriptors/standard_name/ultraviolet_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ultraviolet_index", + "id": "ultraviolet_index", "type": "standard_name", "name": "ultraviolet_index", "description": "The \"Ultraviolet Index\" (UVI) is a measure of the amount of solar ultraviolet radiation that reaches the surface of the earth depending on factors such as time of day and cloud cover. It is often used to alert the public of the need to limit sun exposure and use sun creams to protect the skin. Each point on the Index scale is equivalent to 25 mW m-2 of UV radiation (reference: Australian Bureau of Meteorology, http://www.bom.gov.au/uv/about_uv_index.shtml). The UVI range is expressed as a numeric value from 0 to 20 and sometimes graphically as bands of color indicating the attendant risk of skin damage. A UVI of 0-2 is described as 'Low' (represented graphically in green); a UVI of 11 or greater is described as \"Extreme\" (represented graphically in purple). The higher the UVI, the greater the potential health risk to humans and the less time it takes for harm to occur. To specify the amount of cloud cover at which the data variable applies, provide a scalar coordinate variable with standard name \"cloud_area_fraction\". Standard names are also defined for the quantities ultraviolet_index_assuming_clear_sky and ultraviolet_index_assuming_overcast_sky.", diff --git a/data_descriptors/standard_name/ultraviolet_index_assuming_clear_sky.json b/data_descriptors/standard_name/ultraviolet_index_assuming_clear_sky.json index 6eacf5c0c..c5d041c2e 100644 --- a/data_descriptors/standard_name/ultraviolet_index_assuming_clear_sky.json +++ b/data_descriptors/standard_name/ultraviolet_index_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ultraviolet_index_assuming_clear_sky", + "id": "ultraviolet_index_assuming_clear_sky", "type": "standard_name", "name": "ultraviolet_index_assuming_clear_sky", "description": "The \"Ultraviolet Index\" (UVI) is a measure of the amount of solar ultraviolet radiation that reaches the surface of the earth depending on factors such as time of day and cloud cover. It is often used to alert the public of the need to limit sun exposure and use sun creams to protect the skin. Each point on the Index scale is equivalent to 25 mW m-2 of UV radiation (reference: Australian Bureau of Meteorology, http://www.bom.gov.au/uv/about_uv_index.shtml). The UVI range is expressed as a numeric value from 0 to 20 and sometimes graphically as bands of color indicating the attendant risk of skin damage. A UVI of 0-2 is described as 'Low' (represented graphically in green); a UVI of 11 or greater is described as \"Extreme\" (represented graphically in purple). The higher the UVI, the greater the potential health risk to humans and the less time it takes for harm to occur. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. Standard names are also defined for the quantities ultraviolet_index and ultraviolet_index_assuming_overcast_sky.", diff --git a/data_descriptors/standard_name/ultraviolet_index_assuming_overcast_sky.json b/data_descriptors/standard_name/ultraviolet_index_assuming_overcast_sky.json index 50f4b40a5..3bcc1e64b 100644 --- a/data_descriptors/standard_name/ultraviolet_index_assuming_overcast_sky.json +++ b/data_descriptors/standard_name/ultraviolet_index_assuming_overcast_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/ultraviolet_index_assuming_overcast_sky", + "id": "ultraviolet_index_assuming_overcast_sky", "type": "standard_name", "name": "ultraviolet_index_assuming_overcast_sky", "description": "The \"Ultraviolet Index\" (UVI) is a measure of the amount of solar ultraviolet radiation that reaches the surface of the earth depending on factors such as time of day and cloud cover. It is often used to alert the public of the need to limit sun exposure and use sun creams to protect the skin. Each point on the Index scale is equivalent to 25 mW m-2 of UV radiation (reference: Australian Bureau of Meteorology, http://www.bom.gov.au/uv/about_uv_index.shtml). The UVI range is expressed as a numeric value from 0 to 20 and sometimes graphically as bands of color indicating the attendant risk of skin damage. A UVI of 0-2 is described as 'Low' (represented graphically in green); a UVI of 11 or greater is described as \"Extreme\" (represented graphically in purple). The higher the UVI, the greater the potential health risk to humans and the less time it takes for harm to occur. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Overcast\" means a fractional sky cover of 95% or more when at least a portion of this amount is attributable to clouds or obscuring phenomena (such as haze, dust, smoke, fog, etc.) aloft. (Reference: AMS Glossary: http://glossary.ametsoc.org/wiki/Main_Page). Standard names are also defined for the quantities ultraviolet_index and ultraviolet_index_assuming_clear_sky.", diff --git a/data_descriptors/standard_name/universal_thermal_comfort_index.json b/data_descriptors/standard_name/universal_thermal_comfort_index.json index 5d81578dd..b9bba5b69 100644 --- a/data_descriptors/standard_name/universal_thermal_comfort_index.json +++ b/data_descriptors/standard_name/universal_thermal_comfort_index.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/universal_thermal_comfort_index", + "id": "universal_thermal_comfort_index", "type": "standard_name", "name": "universal_thermal_comfort_index", "description": "Universal Thermal Comfort Index (UTCI) is an equivalent temperature of the actual thermal condition. Reference: utci.org. It is the air temperature of a reference condition causing the same dynamic physiological response in a human body considering its energy budget, physiology and clothing adaptation. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/upward_air_velocity.json b/data_descriptors/standard_name/upward_air_velocity.json index 4499aa664..6b1dec601 100644 --- a/data_descriptors/standard_name/upward_air_velocity.json +++ b/data_descriptors/standard_name/upward_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_air_velocity", + "id": "upward_air_velocity", "type": "standard_name", "name": "upward_air_velocity", "description": "A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector. The standard name downward_air_velocity may be used for a vector component with the opposite sign convention.", diff --git a/data_descriptors/standard_name/upward_derivative_of_eastward_wind.json b/data_descriptors/standard_name/upward_derivative_of_eastward_wind.json index 87acfd1c7..9d431a7db 100644 --- a/data_descriptors/standard_name/upward_derivative_of_eastward_wind.json +++ b/data_descriptors/standard_name/upward_derivative_of_eastward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_derivative_of_eastward_wind", + "id": "upward_derivative_of_eastward_wind", "type": "standard_name", "name": "upward_derivative_of_eastward_wind", "description": "The quantity with standard name upward_derivative_of_eastward_wind is the derivative of the eastward component of wind with respect to height. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/upward_derivative_of_northward_wind.json b/data_descriptors/standard_name/upward_derivative_of_northward_wind.json index 0bae786b3..3c9953b05 100644 --- a/data_descriptors/standard_name/upward_derivative_of_northward_wind.json +++ b/data_descriptors/standard_name/upward_derivative_of_northward_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_derivative_of_northward_wind", + "id": "upward_derivative_of_northward_wind", "type": "standard_name", "name": "upward_derivative_of_northward_wind", "description": "The quantity with standard name upward_derivative_of_northward_wind is the derivative of the northward component of wind speed with respect to height. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/upward_derivative_of_wind_from_direction.json b/data_descriptors/standard_name/upward_derivative_of_wind_from_direction.json index bc78b1382..6751bfb3b 100644 --- a/data_descriptors/standard_name/upward_derivative_of_wind_from_direction.json +++ b/data_descriptors/standard_name/upward_derivative_of_wind_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_derivative_of_wind_from_direction", + "id": "upward_derivative_of_wind_from_direction", "type": "standard_name", "name": "upward_derivative_of_wind_from_direction", "description": "The quantity with standard name upward_derivative_of_wind_from_direction is the derivative of wind from_direction with respect to height. The phrase \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"upward\", \"downward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. A positive value indicates that X is increasing with distance along the positive direction of the axis. The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (\"wind_from_direction\") (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (\"wind_to_direction\") (eastward, southward, etc.). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\").", diff --git a/data_descriptors/standard_name/upward_dry_static_energy_flux_due_to_diffusion.json b/data_descriptors/standard_name/upward_dry_static_energy_flux_due_to_diffusion.json index 2362a607a..84ccd811f 100644 --- a/data_descriptors/standard_name/upward_dry_static_energy_flux_due_to_diffusion.json +++ b/data_descriptors/standard_name/upward_dry_static_energy_flux_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_dry_static_energy_flux_due_to_diffusion", + "id": "upward_dry_static_energy_flux_due_to_diffusion", "type": "standard_name", "name": "upward_dry_static_energy_flux_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves.json b/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves.json index 2072564f1..11885a74d 100644 --- a/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves.json +++ b/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves", + "id": "upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves", "type": "standard_name", "name": "upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Upward eastward\" indicates the ZX component of a tensor. An upward eastward momentum flux is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward. Momentum flux is dimensionally equivalent to stress and pressure. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The total upward eastward momentum flux due to gravity waves is the sum of the fluxes due to orographic gravity waves and nonorographic waves. The upward eastward momentum flux due to orographic gravity waves has the standard name upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves. The total upward eastward momentum flux due to nonorographic gravity waves is the sum of the fluxes due to eastward and westward propagating waves. The latter has the standard name upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves.", diff --git a/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves.json b/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves.json index 0fa15d222..ed44132dd 100644 --- a/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves.json +++ b/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves", + "id": "upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves", "type": "standard_name", "name": "upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Upward eastward\" indicates the ZX component of a tensor. An upward eastward momentum flux is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward. Momentum flux is dimensionally equivalent to stress and pressure. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The total upward eastward momentum flux due to gravity waves is the sum of the fluxes due to orographic gravity waves and nonorographic waves. The upward eastward momentum flux due to orographic gravity waves has the standard name upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves. The total upward eastward momentum flux due to nonorographic gravity waves is the sum of the fluxes due to eastward and westward propagating waves. The former has the standard name upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward _gravity_waves.", diff --git a/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves.json b/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves.json index 36e7482e0..f88d30511 100644 --- a/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves.json +++ b/data_descriptors/standard_name/upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves", + "id": "upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves", "type": "standard_name", "name": "upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Upward eastward\" indicates the ZX component of a tensor. An upward eastward momentum flux is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward. Momentum flux is dimensionally equivalent to stress and pressure. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The total upward eastward momentum flux due to gravity waves is the sum of the fluxes due to orographic gravity waves and nonorographic waves. The total upward eastward momentum flux due to nonorographic gravity waves is the sum of the fluxes due to eastward and westward propagating waves. These quantities have the standard names upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves and upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves, respectively.", diff --git a/data_descriptors/standard_name/upward_eastward_stress_at_sea_ice_base.json b/data_descriptors/standard_name/upward_eastward_stress_at_sea_ice_base.json index eb8667875..6ece08d10 100644 --- a/data_descriptors/standard_name/upward_eastward_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/upward_eastward_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_eastward_stress_at_sea_ice_base", + "id": "upward_eastward_stress_at_sea_ice_base", "type": "standard_name", "name": "upward_eastward_stress_at_sea_ice_base", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. \"Eastward\" indicates a vector component which is positive when directed eastward (negative westward). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Upward eastward\" indicates the ZX component of a tensor. An upward eastward stress is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward.", diff --git a/data_descriptors/standard_name/upward_eliassen_palm_flux_in_air.json b/data_descriptors/standard_name/upward_eliassen_palm_flux_in_air.json index 4b98a1ecb..e6c32adf5 100644 --- a/data_descriptors/standard_name/upward_eliassen_palm_flux_in_air.json +++ b/data_descriptors/standard_name/upward_eliassen_palm_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_eliassen_palm_flux_in_air", + "id": "upward_eliassen_palm_flux_in_air", "type": "standard_name", "name": "upward_eliassen_palm_flux_in_air", "description": "\"Eliassen Palm flux\" is a widely used vector in the meridional plane, and the divergence of this flux appears as a forcing in the Transformed Eulerian mean formulation of the zonal mean zonal wind equation. \"Upward\" indicates a vector component which is positive when directed upward (negative downward).", diff --git a/data_descriptors/standard_name/upward_geothermal_heat_flux_at_sea_floor.json b/data_descriptors/standard_name/upward_geothermal_heat_flux_at_sea_floor.json index 521cabacd..55bdfaefd 100644 --- a/data_descriptors/standard_name/upward_geothermal_heat_flux_at_sea_floor.json +++ b/data_descriptors/standard_name/upward_geothermal_heat_flux_at_sea_floor.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_geothermal_heat_flux_at_sea_floor", + "id": "upward_geothermal_heat_flux_at_sea_floor", "type": "standard_name", "name": "upward_geothermal_heat_flux_at_sea_floor", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_heat_flux_at_base_of_grounded_ice_sheet.json b/data_descriptors/standard_name/upward_heat_flux_at_base_of_grounded_ice_sheet.json index a6a3e80e5..bd22e1a6b 100644 --- a/data_descriptors/standard_name/upward_heat_flux_at_base_of_grounded_ice_sheet.json +++ b/data_descriptors/standard_name/upward_heat_flux_at_base_of_grounded_ice_sheet.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_heat_flux_at_base_of_grounded_ice_sheet", + "id": "upward_heat_flux_at_base_of_grounded_ice_sheet", "type": "standard_name", "name": "upward_heat_flux_at_base_of_grounded_ice_sheet", "description": "In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Grounded ice sheet\" indicates where the ice sheet rests over bedrock and is thus grounded. It excludes ice-caps, glaciers and floating ice shelves. The quantity with standard name upward_heat_flux_at_base_of_grounded_ice_sheet is the upward heat flux at the interface between the ice and bedrock. It does not include any heat flux from the ocean into an ice shelf.", diff --git a/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_snow.json b/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_snow.json index d2ffd0e97..7a402a743 100644 --- a/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_snow.json +++ b/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_snow.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_heat_flux_at_ground_level_in_snow", + "id": "upward_heat_flux_at_ground_level_in_snow", "type": "standard_name", "name": "upward_heat_flux_at_ground_level_in_snow", "description": "ground_level means the land surface (beneath the snow and surface water, if any). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_soil.json b/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_soil.json index 037a0f01d..f170ba304 100644 --- a/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_soil.json +++ b/data_descriptors/standard_name/upward_heat_flux_at_ground_level_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_heat_flux_at_ground_level_in_soil", + "id": "upward_heat_flux_at_ground_level_in_soil", "type": "standard_name", "name": "upward_heat_flux_at_ground_level_in_soil", "description": "ground_level means the land surface (beneath the snow and surface water, if any). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_heat_flux_in_air.json b/data_descriptors/standard_name/upward_heat_flux_in_air.json index 30715fc99..61674d431 100644 --- a/data_descriptors/standard_name/upward_heat_flux_in_air.json +++ b/data_descriptors/standard_name/upward_heat_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_heat_flux_in_air", + "id": "upward_heat_flux_in_air", "type": "standard_name", "name": "upward_heat_flux_in_air", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The vertical heat flux in air is the sum of all heat fluxes i.e. radiative, latent and sensible. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_heat_flux_in_sea_water_due_to_convection.json b/data_descriptors/standard_name/upward_heat_flux_in_sea_water_due_to_convection.json index 250326abe..2bb66f43a 100644 --- a/data_descriptors/standard_name/upward_heat_flux_in_sea_water_due_to_convection.json +++ b/data_descriptors/standard_name/upward_heat_flux_in_sea_water_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_heat_flux_in_sea_water_due_to_convection", + "id": "upward_heat_flux_in_sea_water_due_to_convection", "type": "standard_name", "name": "upward_heat_flux_in_sea_water_due_to_convection", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_latent_heat_flux_in_air.json b/data_descriptors/standard_name/upward_latent_heat_flux_in_air.json index 9c02dc628..cefbd892b 100644 --- a/data_descriptors/standard_name/upward_latent_heat_flux_in_air.json +++ b/data_descriptors/standard_name/upward_latent_heat_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_latent_heat_flux_in_air", + "id": "upward_latent_heat_flux_in_air", "type": "standard_name", "name": "upward_latent_heat_flux_in_air", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The latent heat flux is the exchange of heat across a surface on account of evaporation and condensation (including sublimation and deposition). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_latent_heat_flux_into_air_due_to_transpiration.json b/data_descriptors/standard_name/upward_latent_heat_flux_into_air_due_to_transpiration.json index 96d011460..15728c431 100644 --- a/data_descriptors/standard_name/upward_latent_heat_flux_into_air_due_to_transpiration.json +++ b/data_descriptors/standard_name/upward_latent_heat_flux_into_air_due_to_transpiration.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_latent_heat_flux_into_air_due_to_transpiration", + "id": "upward_latent_heat_flux_into_air_due_to_transpiration", "type": "standard_name", "name": "upward_latent_heat_flux_into_air_due_to_transpiration", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Transpiration is the process by which liquid water in plant stomata is transferred as water vapor into the atmosphere. The latent heat flux due to transpiration is the release of latent heat from plant surfaces to the air due to the release of water vapor.", diff --git a/data_descriptors/standard_name/upward_mass_flux_of_air.json b/data_descriptors/standard_name/upward_mass_flux_of_air.json index 932de0ba7..89c5739d8 100644 --- a/data_descriptors/standard_name/upward_mass_flux_of_air.json +++ b/data_descriptors/standard_name/upward_mass_flux_of_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_mass_flux_of_air", + "id": "upward_mass_flux_of_air", "type": "standard_name", "name": "upward_mass_flux_of_air", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_northward_stress_at_sea_ice_base.json b/data_descriptors/standard_name/upward_northward_stress_at_sea_ice_base.json index 782130b66..562cb002a 100644 --- a/data_descriptors/standard_name/upward_northward_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/upward_northward_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_northward_stress_at_sea_ice_base", + "id": "upward_northward_stress_at_sea_ice_base", "type": "standard_name", "name": "upward_northward_stress_at_sea_ice_base", "description": "\"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs. \"Northward\" indicates a vector component which is positive when directed northward (negative southward). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"Upward northward\" indicates the ZY component of a tensor. An upward northward stress is an upward flux of northward momentum, which accelerates the upper medium northward and the lower medium southward.", diff --git a/data_descriptors/standard_name/upward_ocean_mass_transport.json b/data_descriptors/standard_name/upward_ocean_mass_transport.json index 566a46608..b6926085e 100644 --- a/data_descriptors/standard_name/upward_ocean_mass_transport.json +++ b/data_descriptors/standard_name/upward_ocean_mass_transport.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_ocean_mass_transport", + "id": "upward_ocean_mass_transport", "type": "standard_name", "name": "upward_ocean_mass_transport", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward).", diff --git a/data_descriptors/standard_name/upward_sea_ice_basal_heat_flux.json b/data_descriptors/standard_name/upward_sea_ice_basal_heat_flux.json index 1f3ac6832..e78ac1f23 100644 --- a/data_descriptors/standard_name/upward_sea_ice_basal_heat_flux.json +++ b/data_descriptors/standard_name/upward_sea_ice_basal_heat_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_sea_ice_basal_heat_flux", + "id": "upward_sea_ice_basal_heat_flux", "type": "standard_name", "name": "upward_sea_ice_basal_heat_flux", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The sea ice basal heat flux is the vertical heat flux (apart from radiation i.e. \"diffusive\") in sea water at the base of the sea ice. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/upward_sea_water_velocity.json b/data_descriptors/standard_name/upward_sea_water_velocity.json index df52bf328..d5c4d0155 100644 --- a/data_descriptors/standard_name/upward_sea_water_velocity.json +++ b/data_descriptors/standard_name/upward_sea_water_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_sea_water_velocity", + "id": "upward_sea_water_velocity", "type": "standard_name", "name": "upward_sea_water_velocity", "description": "A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward).", diff --git a/data_descriptors/standard_name/upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json b/data_descriptors/standard_name/upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json index 1f4441754..2fe9d1ee1 100644 --- a/data_descriptors/standard_name/upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json +++ b/data_descriptors/standard_name/upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", + "id": "upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", "type": "standard_name", "name": "upward_sea_water_velocity_due_to_parameterized_mesoscale_eddies", "description": "A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Parameterized mesoscale eddies occur on a spatial scale of many tens of kilometres and an evolutionary time of weeks. Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. Parameterized mesoscale eddies are represented in ocean models using schemes such as the Gent-McWilliams scheme.", diff --git a/data_descriptors/standard_name/upward_sensible_heat_flux_in_air.json b/data_descriptors/standard_name/upward_sensible_heat_flux_in_air.json index a41d631d7..e24668625 100644 --- a/data_descriptors/standard_name/upward_sensible_heat_flux_in_air.json +++ b/data_descriptors/standard_name/upward_sensible_heat_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_sensible_heat_flux_in_air", + "id": "upward_sensible_heat_flux_in_air", "type": "standard_name", "name": "upward_sensible_heat_flux_in_air", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). The sensible heat flux, also called \"turbulent\" heat flux, is the exchange of heat caused by the motion of air. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_transformed_eulerian_mean_air_velocity.json b/data_descriptors/standard_name/upward_transformed_eulerian_mean_air_velocity.json index bbed0ecdb..f0e6c800f 100644 --- a/data_descriptors/standard_name/upward_transformed_eulerian_mean_air_velocity.json +++ b/data_descriptors/standard_name/upward_transformed_eulerian_mean_air_velocity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_transformed_eulerian_mean_air_velocity", + "id": "upward_transformed_eulerian_mean_air_velocity", "type": "standard_name", "name": "upward_transformed_eulerian_mean_air_velocity", "description": "A velocity is a vector quantity. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector. The \"Transformed Eulerian Mean\" refers to a formulation of the mean equations which incorporates some eddy terms into the definition of the mean, described in Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", diff --git a/data_descriptors/standard_name/upward_upward_derivative_of_geopotential.json b/data_descriptors/standard_name/upward_upward_derivative_of_geopotential.json index cc998a1f2..2444a2c86 100644 --- a/data_descriptors/standard_name/upward_upward_derivative_of_geopotential.json +++ b/data_descriptors/standard_name/upward_upward_derivative_of_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_upward_derivative_of_geopotential", + "id": "upward_upward_derivative_of_geopotential", "type": "standard_name", "name": "upward_upward_derivative_of_geopotential", "description": "A quantity with standard name Xward_Yward_derivative_of_geopotential is a second spatial derivative of geopotential in the direction specified by X and Y, i.e., d2P/dXdY. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude.", diff --git a/data_descriptors/standard_name/upward_water_vapor_flux_in_air.json b/data_descriptors/standard_name/upward_water_vapor_flux_in_air.json index 2ed4c531e..108c96dfe 100644 --- a/data_descriptors/standard_name/upward_water_vapor_flux_in_air.json +++ b/data_descriptors/standard_name/upward_water_vapor_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_water_vapor_flux_in_air", + "id": "upward_water_vapor_flux_in_air", "type": "standard_name", "name": "upward_water_vapor_flux_in_air", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_water_vapor_flux_in_air_due_to_diffusion.json b/data_descriptors/standard_name/upward_water_vapor_flux_in_air_due_to_diffusion.json index 2962553fc..cd2d03fa3 100644 --- a/data_descriptors/standard_name/upward_water_vapor_flux_in_air_due_to_diffusion.json +++ b/data_descriptors/standard_name/upward_water_vapor_flux_in_air_due_to_diffusion.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_water_vapor_flux_in_air_due_to_diffusion", + "id": "upward_water_vapor_flux_in_air_due_to_diffusion", "type": "standard_name", "name": "upward_water_vapor_flux_in_air_due_to_diffusion", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Upward\" indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upward_x_stress_at_sea_ice_base.json b/data_descriptors/standard_name/upward_x_stress_at_sea_ice_base.json index bcb715064..d66b84292 100644 --- a/data_descriptors/standard_name/upward_x_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/upward_x_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_x_stress_at_sea_ice_base", + "id": "upward_x_stress_at_sea_ice_base", "type": "standard_name", "name": "upward_x_stress_at_sea_ice_base", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"x\" indicates a vector component along the grid x-axis, positive with increasing x. \"Upward x\" indicates the ZX component of a tensor. An upward x stress is an upward flux of x-ward momentum, which accelerates the upper medium in the positive x direction and the lower medium in the negative x direction.", diff --git a/data_descriptors/standard_name/upward_y_stress_at_sea_ice_base.json b/data_descriptors/standard_name/upward_y_stress_at_sea_ice_base.json index 0be97aba7..864dda5fd 100644 --- a/data_descriptors/standard_name/upward_y_stress_at_sea_ice_base.json +++ b/data_descriptors/standard_name/upward_y_stress_at_sea_ice_base.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upward_y_stress_at_sea_ice_base", + "id": "upward_y_stress_at_sea_ice_base", "type": "standard_name", "name": "upward_y_stress_at_sea_ice_base", "description": "\"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"y\" indicates a vector component along the grid y-axis, positive with increasing y. \"Upward y\" indicates the ZY component of a tensor. An upward y-ward stress is an upward flux of momentum, which accelerates the upper medium in the positive y direction and the lower medium in the negative y direction.", diff --git a/data_descriptors/standard_name/upwelling_longwave_flux_in_air.json b/data_descriptors/standard_name/upwelling_longwave_flux_in_air.json index f612ebc03..fad26cdf1 100644 --- a/data_descriptors/standard_name/upwelling_longwave_flux_in_air.json +++ b/data_descriptors/standard_name/upwelling_longwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_longwave_flux_in_air", + "id": "upwelling_longwave_flux_in_air", "type": "standard_name", "name": "upwelling_longwave_flux_in_air", "description": "The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky.json index 4b4f943ae..1b317c340 100644 --- a/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky", + "id": "upwelling_longwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "upwelling_longwave_flux_in_air_assuming_clear_sky", "description": "The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 0c88a66b9..642c6ccb6 100644 --- a/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "upwelling_longwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index 76d31f3f8..3ddaa8e2a 100644 --- a/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "upwelling_longwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/upwelling_longwave_radiance_in_air.json b/data_descriptors/standard_name/upwelling_longwave_radiance_in_air.json index ea4bdfbeb..295987e6c 100644 --- a/data_descriptors/standard_name/upwelling_longwave_radiance_in_air.json +++ b/data_descriptors/standard_name/upwelling_longwave_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_longwave_radiance_in_air", + "id": "upwelling_longwave_radiance_in_air", "type": "standard_name", "name": "upwelling_longwave_radiance_in_air", "description": "The term \"longwave\" means longwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/upwelling_radiance_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/upwelling_radiance_per_unit_wavelength_in_air.json index 83710d38e..9ca138b15 100644 --- a/data_descriptors/standard_name/upwelling_radiance_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/upwelling_radiance_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_radiance_per_unit_wavelength_in_air", + "id": "upwelling_radiance_per_unit_wavelength_in_air", "type": "standard_name", "name": "upwelling_radiance_per_unit_wavelength_in_air", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_air.json b/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_air.json index a69939301..1939e5323 100644 --- a/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_air.json +++ b/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_radiative_flux_per_unit_wavelength_in_air", + "id": "upwelling_radiative_flux_per_unit_wavelength_in_air", "type": "standard_name", "name": "upwelling_radiative_flux_per_unit_wavelength_in_air", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json b/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json index e035c6f03..c8c3ea8db 100644 --- a/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json +++ b/data_descriptors/standard_name/upwelling_radiative_flux_per_unit_wavelength_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_radiative_flux_per_unit_wavelength_in_sea_water", + "id": "upwelling_radiative_flux_per_unit_wavelength_in_sea_water", "type": "standard_name", "name": "upwelling_radiative_flux_per_unit_wavelength_in_sea_water", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A coordinate variable for radiation wavelength should be given the standard name radiation_wavelength.", diff --git a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air.json b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air.json index 85c72652d..ab1652c1c 100644 --- a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air.json +++ b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_shortwave_flux_in_air", + "id": "upwelling_shortwave_flux_in_air", "type": "standard_name", "name": "upwelling_shortwave_flux_in_air", "description": "The term \"shortwave\" means shortwave radiation. Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky.json b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky.json index f20ab33be..18432c35f 100644 --- a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky.json +++ b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky", + "id": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "type": "standard_name", "name": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json index 2c5ce3818..53a055598 100644 --- a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json +++ b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", + "id": "upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "type": "standard_name", "name": "upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds.", diff --git a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json index 1b55cf301..14286a4c2 100644 --- a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", + "id": "upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "upwelling_shortwave_flux_in_air_assuming_clear_sky_and_reference_mole_fraction_of_ozone_in_air", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Clear sky\" means in the absence of clouds. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json index 53e5637de..aefb7bb51 100644 --- a/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json +++ b/data_descriptors/standard_name/upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", + "id": "upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "type": "standard_name", "name": "upwelling_shortwave_flux_in_air_assuming_reference_mole_fraction_of_ozone_in_air", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. This 3D ozone field acts as a reference ozone field in a diagnostic call to the model's radiation scheme. It is expressed in terms of mole fraction of ozone in air. It may be observation-based or model-derived. It may be from any time period. By using the same ozone reference in the diagnostic radiation call in two model simulations and calculating differences between the radiative flux diagnostics from the prognostic call to the radiation scheme and the diagnostic call to the radiation scheme with the ozone reference, an instantaneous radiative forcing for ozone can be calculated.", diff --git a/data_descriptors/standard_name/upwelling_shortwave_radiance_in_air.json b/data_descriptors/standard_name/upwelling_shortwave_radiance_in_air.json index 5840b8750..70d02994d 100644 --- a/data_descriptors/standard_name/upwelling_shortwave_radiance_in_air.json +++ b/data_descriptors/standard_name/upwelling_shortwave_radiance_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/upwelling_shortwave_radiance_in_air", + "id": "upwelling_shortwave_radiance_in_air", "type": "standard_name", "name": "upwelling_shortwave_radiance_in_air", "description": "Upwelling radiation is radiation from below. It does not mean \"net upward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. The term \"shortwave\" means shortwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.", diff --git a/data_descriptors/standard_name/vegetation_area_fraction.json b/data_descriptors/standard_name/vegetation_area_fraction.json index 563ec866e..85f22e51d 100644 --- a/data_descriptors/standard_name/vegetation_area_fraction.json +++ b/data_descriptors/standard_name/vegetation_area_fraction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vegetation_area_fraction", + "id": "vegetation_area_fraction", "type": "standard_name", "name": "vegetation_area_fraction", "description": "\"Area fraction\" is the fraction of a grid cell's horizontal area that has some characteristic of interest. It is evaluated as the area of interest divided by the grid cell area, or if the cell_methods restricts the evaluation to some portion of that grid cell (e.g. \"where sea_ice\"), then it is the area of interest divided by the area of the identified portion. It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Vegetation\" means any plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/vegetation_carbon_content.json b/data_descriptors/standard_name/vegetation_carbon_content.json index 118788c50..0205c6e8f 100644 --- a/data_descriptors/standard_name/vegetation_carbon_content.json +++ b/data_descriptors/standard_name/vegetation_carbon_content.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vegetation_carbon_content", + "id": "vegetation_carbon_content", "type": "standard_name", "name": "vegetation_carbon_content", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any plants e.g. trees, shrubs, grass. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/vegetation_mass_content_of_13C.json b/data_descriptors/standard_name/vegetation_mass_content_of_13C.json index 27e1ecb5f..ed5f67a1c 100644 --- a/data_descriptors/standard_name/vegetation_mass_content_of_13C.json +++ b/data_descriptors/standard_name/vegetation_mass_content_of_13C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vegetation_mass_content_of_13C", + "id": "vegetation_mass_content_of_13C", "type": "standard_name", "name": "vegetation_mass_content_of_13C", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"C\" means the element carbon and \"13C\" is the stable isotope \"carbon-13\", having six protons and seven neutrons.", diff --git a/data_descriptors/standard_name/vegetation_mass_content_of_14C.json b/data_descriptors/standard_name/vegetation_mass_content_of_14C.json index 86ba5953b..69c8bf166 100644 --- a/data_descriptors/standard_name/vegetation_mass_content_of_14C.json +++ b/data_descriptors/standard_name/vegetation_mass_content_of_14C.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vegetation_mass_content_of_14C", + "id": "vegetation_mass_content_of_14C", "type": "standard_name", "name": "vegetation_mass_content_of_14C", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. \"C\" means the element carbon and \"14C\" is the radioactive isotope \"carbon-14\", having six protons and eight neutrons and used in radiocarbon dating.", diff --git a/data_descriptors/standard_name/vegetation_mass_content_of_nitrogen.json b/data_descriptors/standard_name/vegetation_mass_content_of_nitrogen.json index ab2182f21..b009a887c 100644 --- a/data_descriptors/standard_name/vegetation_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/vegetation_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vegetation_mass_content_of_nitrogen", + "id": "vegetation_mass_content_of_nitrogen", "type": "standard_name", "name": "vegetation_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"Vegetation\" means any living plants e.g. trees, shrubs, grass. The term \"plants\" refers to the kingdom of plants in the modern classification which excludes fungi. Plants are autotrophs i.e. \"producers\" of biomass using carbon obtained from carbon dioxide.", diff --git a/data_descriptors/standard_name/vertical_component_of_ocean_xy_tracer_diffusivity.json b/data_descriptors/standard_name/vertical_component_of_ocean_xy_tracer_diffusivity.json index 3cb8aac3e..9c7a9d9e3 100644 --- a/data_descriptors/standard_name/vertical_component_of_ocean_xy_tracer_diffusivity.json +++ b/data_descriptors/standard_name/vertical_component_of_ocean_xy_tracer_diffusivity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vertical_component_of_ocean_xy_tracer_diffusivity", + "id": "vertical_component_of_ocean_xy_tracer_diffusivity", "type": "standard_name", "name": "vertical_component_of_ocean_xy_tracer_diffusivity", "description": "The vertical_component_of_ocean_xy_tracer_diffusivity means the vertical component of the diffusivity of tracers in the ocean due to lateral mixing. This quantity could appear in formulations of lateral diffusivity in which \"lateral\" does not mean \"iso-level\", e.g. it would not be used for isopycnal diffusivity. \"Tracer diffusivity\" means the diffusivity of heat and salinity due to motion which is not resolved on the grid scale of the model.", diff --git a/data_descriptors/standard_name/vertical_navigation_clearance_above_waterway_surface.json b/data_descriptors/standard_name/vertical_navigation_clearance_above_waterway_surface.json index c4694b6b7..a8f744160 100644 --- a/data_descriptors/standard_name/vertical_navigation_clearance_above_waterway_surface.json +++ b/data_descriptors/standard_name/vertical_navigation_clearance_above_waterway_surface.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/vertical_navigation_clearance_above_waterway_surface", + "id": "vertical_navigation_clearance_above_waterway_surface", "type": "standard_name", "name": "vertical_navigation_clearance_above_waterway_surface", "description": "\"Vertical navigation clearance\" is the vertical distance between the surface of a navigable waterway and a hazard above it such as a bridge. It is a time-varying quantity because the clearance distance is due to all processes that change the position of either the surface or the hazard. \"Waterway surface\" means the upper boundary of any body of navigable water.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_correction.json b/data_descriptors/standard_name/virtual_salt_flux_correction.json index 93ef315be..df95813cb 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_correction.json +++ b/data_descriptors/standard_name/virtual_salt_flux_correction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_correction", + "id": "virtual_salt_flux_correction", "type": "standard_name", "name": "virtual_salt_flux_correction", "description": "The virtual_salt_flux_into_sea_water_due_to_process is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_process. Flux correction is also called \"flux adjustment\". A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water.json b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water.json index 1ba6f6f8a..f236ec520 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water.json +++ b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_into_sea_water", + "id": "virtual_salt_flux_into_sea_water", "type": "standard_name", "name": "virtual_salt_flux_into_sea_water", "description": "The virtual_salt_flux_into_sea_water is the salt flux that would have the same effect on the sea surface salinity as the water_flux_out_of_sea_water. It includes the effects of precipitation, evaporation, river outflow, sea-ice and any water flux relaxation(s) and correction(s) that may have been applied. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_evaporation.json b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_evaporation.json index 800b7c2e5..4d9eba2a3 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_evaporation.json +++ b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_evaporation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_into_sea_water_due_to_evaporation", + "id": "virtual_salt_flux_into_sea_water_due_to_evaporation", "type": "standard_name", "name": "virtual_salt_flux_into_sea_water_due_to_evaporation", "description": "The virtual_salt_flux_into_sea_water_due_to_process is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_process. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation.json b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation.json index 288dce74c..cd491453d 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation.json +++ b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation", + "id": "virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation", "type": "standard_name", "name": "virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_newtonian_relaxation. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_rainfall.json b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_rainfall.json index 721d599f1..57385b0d9 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_rainfall.json +++ b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_rainfall.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_into_sea_water_due_to_rainfall", + "id": "virtual_salt_flux_into_sea_water_due_to_rainfall", "type": "standard_name", "name": "virtual_salt_flux_into_sea_water_due_to_rainfall", "description": "The virtual_salt_flux_into_sea_water_due_to_process is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_process. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json index 116aee121..60152b353 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", + "id": "virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", "description": "The virtual_salt_flux_into_sea_water_due_to_process is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_process. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_from_rivers.json b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_from_rivers.json index bbfde7e63..e0c9dc3fc 100644 --- a/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_from_rivers.json +++ b/data_descriptors/standard_name/virtual_salt_flux_into_sea_water_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_salt_flux_into_sea_water_from_rivers", + "id": "virtual_salt_flux_into_sea_water_from_rivers", "type": "standard_name", "name": "virtual_salt_flux_into_sea_water_from_rivers", "description": "The virtual_salt_flux_into_sea_water_due_to_process is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_process. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/virtual_temperature.json b/data_descriptors/standard_name/virtual_temperature.json index 1665455d8..01b5a1246 100644 --- a/data_descriptors/standard_name/virtual_temperature.json +++ b/data_descriptors/standard_name/virtual_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/virtual_temperature", + "id": "virtual_temperature", "type": "standard_name", "name": "virtual_temperature", "description": "The virtual temperature of air is the temperature at which the dry air constituent of a parcel of moist air would have the same density as the moist air at the same pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/visibility_in_air.json b/data_descriptors/standard_name/visibility_in_air.json index 6fae4e3f5..e86309947 100644 --- a/data_descriptors/standard_name/visibility_in_air.json +++ b/data_descriptors/standard_name/visibility_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/visibility_in_air", + "id": "visibility_in_air", "type": "standard_name", "name": "visibility_in_air", "description": "The visibility is the distance at which something can be seen.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json index 34d5427cb..6200d063f 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json index b6f218ae2..c6be99b37 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json index de8e61f2b..fbe08f9c8 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index baff2fce8..90de1407c 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with \"specific_\" instead of \"volume_\". A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json index 9bb3a013a..de14ea92d 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with \"specific_\" instead of \"volume_\". The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths unless a coordinate of \"radiation_wavelength\" or \"radiation_frequency\" is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol\" means that the aerosol sample has been dried from the ambient state, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json index e2be391b2..a42ab0899 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json index a116c3945..03283c412 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json index fa3c40561..7347ba4a6 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json index dada3202a..3dad02faf 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json index 222973ee1..68f8d7c1c 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json index 860c2295e..d39587375 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index 54c7a49d4..bcc78fc50 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json index b874273e3..987257750 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json index c6c28cdc4..6a30888e6 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json index 702378fbf..63d90cdf2 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 964e10c89..22e98a4a5 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json index edb74660f..1283a8b6f 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json index 2063405b8..ae613e40b 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json index 1f142ddd7..1b6059284 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index ab2b47b9a..da3b0c0e9 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json index 27b1bdb61..d0ee3b4e4 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 6fd138cd6..6dee1ab1b 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json index 2559210ad..1628d1513 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json index ec7cbcc8c..7a5b8a2a2 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json index 1b9cdcdf6..34281a898 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", "description": "The volume scattering coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json index 6bb74732e..451a2aaad 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json index afb027039..592f16d5c 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index e766d4778..2beeeb110 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json index 0d2fb0ceb..e31a436a6 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 2b984cb98..e702226dc 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json index 3c2b5439c..b9aff61fc 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json index fa7872ad8..4eb367894 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water.json index 86d40e1d7..b88c7f09e 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water", + "id": "volume_absorption_coefficient_of_radiative_flux_in_sea_water", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_sea_water", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength.", diff --git a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter.json b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter.json index 32515855c..dca0f834c 100644 --- a/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter.json +++ b/data_descriptors/standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter", + "id": "volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter", "type": "standard_name", "name": "volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength.", diff --git a/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air.json b/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air.json index e38226cdc..f778dfe7c 100644 --- a/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air.json +++ b/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air", + "id": "volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air", "type": "standard_name", "name": "volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air", "description": "Attenuation is the sum of absorption and scattering. Attenuation is sometimes called \"extinction\". The attenuated backwards scattering function includes the effects of two-way attenuation by the medium between a radar source and receiver. The volume scattering function is the fraction of incident radiative flux scattered into unit solid angle per unit path length. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity.", diff --git a/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud.json b/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud.json index baef7c322..52f385e67 100644 --- a/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud.json +++ b/data_descriptors/standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud", + "id": "volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud", "type": "standard_name", "name": "volume_attenuated_backwards_scattering_coefficient_of_radiative_flux_in_air_assuming_no_aerosol_or_cloud", "description": "Attenuation is the sum of absorption and scattering. Attenuation is sometimes called \"extinction\". The attenuated backwards scattering coefficient includes the effects of two-way attenuation by the medium between a radar source and receiver. The volume scattering coefficient is the fraction of incident radiative flux scattered into unit solid angle per unit path length. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering coefficient is assumed to be an integral over all wavelengths unless a coordinate of \"radiation_wavelength\" or \"radiation_frequency\" is included to specify the wavelength. Coefficients with canonical units of m2 s-1, i.e. multiplied by density, have standard names with \"specific_\" instead of \"volume_\". Radiative flux is the sum of shortwave and longwave radiative fluxes. A phrase \"assuming_condition\" indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself.", diff --git a/data_descriptors/standard_name/volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water.json index 146c85765..e0dd855dc 100644 --- a/data_descriptors/standard_name/volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water", + "id": "volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water", "type": "standard_name", "name": "volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water", "description": "Downwelling radiation is radiation from above. It does not mean \"net downward\". The sign convention is that \"upwelling\" is positive upwards and \"downwelling\" is positive downwards. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called \"irradiance\". In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called \"vector irradiance\". In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Attenuation is the sum of absorption and scattering. Attenuation is sometimes called \"extinction\". Also called \"diffuse\" attenuation, the attenuation of downwelling radiative flux refers to the decrease with decreasing height or increasing depth of the downwelling component of radiative flux, regardless of incident direction.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json index 54ddbf36a..deab433a0 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_by_ranging_instrument_in_air_due_to_ambient_aerosol_particles", "description": "Volume backwards scattering coefficient by ranging instrument is the fraction of radiative flux, per unit path length and per unit solid angle, scattered at 180 degrees angle respect to the incident radiation and obtained through ranging techniques like lidar and radar. Backwards scattering coefficient is assumed to be related to the same wavelength of incident radiation. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json index 0a5d42e45..0b867f053 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json index b08c7e9e9..40defc694 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json index e68ea1cba..cf92b784e 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index d1c60b04e..fa0fe55a1 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json index d4d1db3a1..bb58c374a 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol\" means that the aerosol sample has been dried from the ambient state, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 4d785030d..228b98b85 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json index 27ccbd3eb..7a15b2160 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 5cb1b13cb..15376e205 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json index f0fcc8e6c..833d86ddf 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json index 859e33487..cf72ed354 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json index 7f1f13838..52e847971 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index a74a508ff..47621b71d 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json index 9a23c95b3..546661047 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 1fcb7424c..4ec1edfe8 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json index 6fe9207a8..7c6aa4f74 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 249c81b49..c1da5fc98 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json index 798ed3b50..a8170e673 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json index ff148da5e..84968788d 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json index 1a77a2b49..1ff30f8d3 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index b9a261c3f..a18f69b2b 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json index 91d251b62..0117eea18 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 9572752b0..ed7fd21b8 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json index 191a09e39..a50258af9 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 80940dd0d..1c511b76f 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json index afccde753..acb55e7b6 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json index 2acd0e908..f22c495ff 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json index 9237ed109..296c2b303 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index 8557b17c6..96b13d053 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json index 29fc6590c..cf1fc4b2e 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json index da2ec5c71..a0044a12b 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json index 1d6a71075..8c866c4cd 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json index a90b0d122..209a55525 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeds pi/2 radians. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water.json index 3a64e348d..21dfd3d67 100644 --- a/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water", + "id": "volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water", "type": "standard_name", "name": "volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Scattering of radiation is its deflection from its incident path without loss of energy. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity.", diff --git a/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water.json index 850d1542d..0e915cb36 100644 --- a/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water", + "id": "volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water", "type": "standard_name", "name": "volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Attenuation is the sum of absorption and scattering. Attenuation is sometimes called \"extinction\". Beam attenuation refers to the decrease of radiative flux along the direction of the incident path. It is distinguished from attenuation of the downwelling component of radiative flux from any incident direction, also called \"diffuse\" attenuation.", diff --git a/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance.json b/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance.json index 86525fdfb..369522cdb 100644 --- a/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance.json +++ b/data_descriptors/standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance", + "id": "volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance", "type": "standard_name", "name": "volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water_corrected_for_pure_water_attenuance", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Attenuation is the sum of absorption and scattering. Attenuation is sometimes called \"extinction\". Beam attenuation refers to the decrease of radiative flux along the direction of the incident path. It is distinguished from attenuation of the downwelling component of radiative flux from any incident direction, also called \"diffuse\" attenuation. The phrase \"corrected for pure water attenuance\" means the attenuation coefficient has been adjusted/calibrated to remove the influence of absorption/scattering by the water itself. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_.", diff --git a/data_descriptors/standard_name/volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles.json index 8ec271068..c2ce4fd0f 100644 --- a/data_descriptors/standard_name/volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles", + "id": "volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_extinction_angstrom_exponent_in_air_due_to_ambient_aerosol_particles", "description": "The volume extinction Angstrom exponent is the Angstrom exponent obtained for the aerosol extinction instead that for the aerosol optical thickness. It is alpha in the following equation relating aerosol extinction (ext) at the wavelength lambda to aerosol extinction at a different wavelength lambda0: ext(lambda) = ext(lambda0) * [lambda/lambda0] ** (-1 * alpha). \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json index 95f6fe37f..b668922ed 100644 --- a/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", + "id": "volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_extinction_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "description": "The volume extinction coefficient is the fractional change of radiative flux per unit path length. Extinction is the sum of absorption and scattering, sometimes called \"attenuation\". \"Extinction\" is the term most commonly used at optical wavelengths whereas \"attenuation\" is more often used at radio and radar wavelengths. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles.json b/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles.json index 49de6f945..20e2a314d 100644 --- a/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles.json +++ b/data_descriptors/standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles", + "id": "volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles", "type": "standard_name", "name": "volume_extinction_coefficient_of_radiative_flux_in_air_due_to_cloud_particles", "description": "The volume extinction coefficient is the fractional change of radiative flux per unit path length. Extinction is the sum of absorption and scattering, sometimes called \"attenuation\". \"Extinction\" is the term most commonly used at optical wavelengths whereas \"attenuation\" is more often used at radio and radar wavelengths. Radiative flux is the sum of shortwave and longwave radiative fluxes. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Cloud particles\" means suspended liquid or ice water droplets. A coordinate of radiation_wavelength or radiation_frequency should be included to specify either the wavelength or frequency.", diff --git a/data_descriptors/standard_name/volume_fraction_of_clay_in_soil.json b/data_descriptors/standard_name/volume_fraction_of_clay_in_soil.json index 8a8491bbc..e8cd3f007 100644 --- a/data_descriptors/standard_name/volume_fraction_of_clay_in_soil.json +++ b/data_descriptors/standard_name/volume_fraction_of_clay_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_clay_in_soil", + "id": "volume_fraction_of_clay_in_soil", "type": "standard_name", "name": "volume_fraction_of_clay_in_soil", "description": "\"Volume fraction\" is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil.json b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil.json index 0b48aff35..7674369dc 100644 --- a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil.json +++ b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_condensed_water_in_soil", + "id": "volume_fraction_of_condensed_water_in_soil", "type": "standard_name", "name": "volume_fraction_of_condensed_water_in_soil", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The phrase \"condensed_water\" means liquid and ice.", diff --git a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_critical_point.json b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_critical_point.json index 14ae67e19..b4fe395a1 100644 --- a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_critical_point.json +++ b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_critical_point.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_condensed_water_in_soil_at_critical_point", + "id": "volume_fraction_of_condensed_water_in_soil_at_critical_point", "type": "standard_name", "name": "volume_fraction_of_condensed_water_in_soil_at_critical_point", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The phrase \"condensed_water\" means liquid and ice. When soil moisture equals or exceeds the critical point, evapotranspiration takes place at the potential rate and is controlled by the ambient meteorological conditions (temperature, wind, relative humidity). Potential evapotranspiration is the rate at which evapotranspiration would occur under ambient conditions from a uniformly vegetated area when the water supply is not limiting.", diff --git a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_field_capacity.json b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_field_capacity.json index e77d90268..ce68435ea 100644 --- a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_field_capacity.json +++ b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_field_capacity.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_condensed_water_in_soil_at_field_capacity", + "id": "volume_fraction_of_condensed_water_in_soil_at_field_capacity", "type": "standard_name", "name": "volume_fraction_of_condensed_water_in_soil_at_field_capacity", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The phrase \"condensed_water\" means liquid and ice. The field capacity of soil is the maximum content of water it can retain against gravitational drainage.", diff --git a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_wilting_point.json b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_wilting_point.json index 1ed8afda8..fc8d50a7e 100644 --- a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_wilting_point.json +++ b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_at_wilting_point.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_condensed_water_in_soil_at_wilting_point", + "id": "volume_fraction_of_condensed_water_in_soil_at_wilting_point", "type": "standard_name", "name": "volume_fraction_of_condensed_water_in_soil_at_wilting_point", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The phrase \"condensed_water\" means liquid and ice. The wilting point of soil is the water content below which plants cannot extract sufficient water to balance their loss through transpiration.", diff --git a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_pores.json b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_pores.json index 80e619b8c..421c89605 100644 --- a/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_pores.json +++ b/data_descriptors/standard_name/volume_fraction_of_condensed_water_in_soil_pores.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_condensed_water_in_soil_pores", + "id": "volume_fraction_of_condensed_water_in_soil_pores", "type": "standard_name", "name": "volume_fraction_of_condensed_water_in_soil_pores", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Condensed water\" means liquid and ice. The quantity with standard name volume_fraction_of_condensed_water_in_soil_pores is the ratio of the volume of condensed water in soil pores to the volume of the pores themselves.", diff --git a/data_descriptors/standard_name/volume_fraction_of_frozen_water_in_soil.json b/data_descriptors/standard_name/volume_fraction_of_frozen_water_in_soil.json index 990a82bec..4109885a3 100644 --- a/data_descriptors/standard_name/volume_fraction_of_frozen_water_in_soil.json +++ b/data_descriptors/standard_name/volume_fraction_of_frozen_water_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_frozen_water_in_soil", + "id": "volume_fraction_of_frozen_water_in_soil", "type": "standard_name", "name": "volume_fraction_of_frozen_water_in_soil", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The phrase \"frozen_water\" means ice.", diff --git a/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water.json b/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water.json index 1508ff5cc..4d7371461 100644 --- a/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water.json +++ b/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water", + "id": "volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water", "type": "standard_name", "name": "volume_fraction_of_oxygen_in_sea_floor_sediment_pore_water", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Sea floor sediment\" is sediment deposited at the sea bed. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_water.json b/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_water.json index 876109f76..35d29c241 100644 --- a/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_water.json +++ b/data_descriptors/standard_name/volume_fraction_of_oxygen_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_oxygen_in_sea_water", + "id": "volume_fraction_of_oxygen_in_sea_water", "type": "standard_name", "name": "volume_fraction_of_oxygen_in_sea_water", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/volume_fraction_of_pelite_in_sea_floor_sediment.json b/data_descriptors/standard_name/volume_fraction_of_pelite_in_sea_floor_sediment.json index f9d866c68..3abf17aef 100644 --- a/data_descriptors/standard_name/volume_fraction_of_pelite_in_sea_floor_sediment.json +++ b/data_descriptors/standard_name/volume_fraction_of_pelite_in_sea_floor_sediment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_pelite_in_sea_floor_sediment", + "id": "volume_fraction_of_pelite_in_sea_floor_sediment", "type": "standard_name", "name": "volume_fraction_of_pelite_in_sea_floor_sediment", "description": "\"Volume fraction\" is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. \"Sea floor sediment\" is sediment deposited at the sea bed. \"Pelite\" is sediment less than 0.063 millimeters in diameter.", diff --git a/data_descriptors/standard_name/volume_fraction_of_sand_in_soil.json b/data_descriptors/standard_name/volume_fraction_of_sand_in_soil.json index c2fec6130..b77c8b66f 100644 --- a/data_descriptors/standard_name/volume_fraction_of_sand_in_soil.json +++ b/data_descriptors/standard_name/volume_fraction_of_sand_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_sand_in_soil", + "id": "volume_fraction_of_sand_in_soil", "type": "standard_name", "name": "volume_fraction_of_sand_in_soil", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/volume_fraction_of_silt_in_soil.json b/data_descriptors/standard_name/volume_fraction_of_silt_in_soil.json index 7b0dd9444..9a9fdfabc 100644 --- a/data_descriptors/standard_name/volume_fraction_of_silt_in_soil.json +++ b/data_descriptors/standard_name/volume_fraction_of_silt_in_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_silt_in_soil", + "id": "volume_fraction_of_silt_in_soil", "type": "standard_name", "name": "volume_fraction_of_silt_in_soil", "description": "\"Volume fraction\" is used in the construction \"volume_fraction_of_X_in_Y\", where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction.", diff --git a/data_descriptors/standard_name/volume_fraction_of_water_in_soil_at_saturation.json b/data_descriptors/standard_name/volume_fraction_of_water_in_soil_at_saturation.json index 55b1ebe99..47b40c95f 100644 --- a/data_descriptors/standard_name/volume_fraction_of_water_in_soil_at_saturation.json +++ b/data_descriptors/standard_name/volume_fraction_of_water_in_soil_at_saturation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_fraction_of_water_in_soil_at_saturation", + "id": "volume_fraction_of_water_in_soil_at_saturation", "type": "standard_name", "name": "volume_fraction_of_water_in_soil_at_saturation", "description": "\"Volume fraction\" is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y. It is evaluated as the volume of X divided by the volume of Y (including X). It may be expressed as a fraction, a percentage, or any other dimensionless representation of a fraction. The volume_fraction_of_water_in_soil_at_saturation is the volume fraction at which a soil has reached it's maximum water holding capacity.", diff --git a/data_descriptors/standard_name/volume_mixing_ratio_of_oxygen_at_stp_in_sea_water.json b/data_descriptors/standard_name/volume_mixing_ratio_of_oxygen_at_stp_in_sea_water.json index a1dd73540..025f3c96e 100644 --- a/data_descriptors/standard_name/volume_mixing_ratio_of_oxygen_at_stp_in_sea_water.json +++ b/data_descriptors/standard_name/volume_mixing_ratio_of_oxygen_at_stp_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_mixing_ratio_of_oxygen_at_stp_in_sea_water", + "id": "volume_mixing_ratio_of_oxygen_at_stp_in_sea_water", "type": "standard_name", "name": "volume_mixing_ratio_of_oxygen_at_stp_in_sea_water", "description": "\"ratio_of_X_to_Y\" means X/Y. \"stp\" means standard temperature (0 degC) and pressure (101325 Pa).", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json index d7624b77a..eb25de6d2 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json index 266e7a0e2..3fc6a4015 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json index ceac98c79..9b4fc5b06 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. Scattering of radiation is its deflection from its incident path without loss of energy. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with \"specific_\" instead of \"volume_\". The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths unless a coordinate of \"radiation_wavelength\" or \"radiation_frequency\" is included to specify the wavelength. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exist in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the quantity described by the standard name applies, provide a scalar coordinate variable with the standard name of \"relative_humidity\".", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index f6851c97e..05aa272be 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json index 4af9200e0..679896f0d 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. Scattering of radiation is its deflection from its incident path without loss of energy. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with \"specific_\" instead of \"volume_\". The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths unless a coordinate of \"radiation_wavelength\" or \"radiation_frequency\" is included to specify the wavelength. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\".", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 3e81d4e8e..66aa4abcb 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json index 3a90c95b2..a876895f5 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 9f3039d41..0fc60c4dc 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json index 0228dc0ee..904ebabdb 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json index 089024cde..588fb3f5e 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json index 34e99af3f..f61c3c9b6 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index 76cab7c55..5763727b3 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json index a358e6b0f..3210d1945 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json index fa2d20810..7b66e992b 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json index 66c0bc5e5..c6cbe4b7d 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 40054b66c..0b6a01fc7 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm10_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json index 274f3ff3d..2b512fdf7 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json index 5fc23e7dd..cb739df61 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json index b09d51d99..9e0094a48 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index d38415f58..b7324230e 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json index cc5484ceb..c44c38cb5 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json index 7ecee4254..0a9d34097 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json index 6aca8b83c..bcfa73740 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json index 8b185aec9..d6bb09268 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm1_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm1 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json index 43e63bf32..c64325c76 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json index 64cea0a0a..f29b3c15d 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json index 386c51337..99c559abd 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json index ee2cb9151..8b1e25f8d 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_ambient_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json index c014294b8..8e876f2c1 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm10 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json index b2354a0a0..47fb3e5d1 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dried_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Dried_aerosol_particles\" means that the aerosol sample has been dried from the ambient state before sizing, but that the dry state (relative humidity less than 40 per cent) has not necessarily been reached. To specify the relative humidity at which the sample was measured, provide a scalar coordinate variable with the standard name of \"relative_humidity\". The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json index 89a29b16b..41ed54f4c 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json index a8225dbb4..cdb5993a2 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", + "id": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_air_due_to_pm2p5_dry_aerosol_particles_at_standard_temperature_and_pressure", "description": "The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. A scattering_angle should not be specified with this quantity. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Radiative flux is the sum of shortwave and longwave radiative fluxes. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. \"Dry aerosol particles\" means aerosol particles without any water uptake. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Pm2p5 aerosol particles\" means atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. \"Standard_temperature_and_pressure\" refer to a reference volume at 273.15 K temperature and 1013.25 hPa pressure.", diff --git a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_sea_water.json index 1d814dc93..bffab0ff7 100644 --- a/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/volume_scattering_coefficient_of_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_coefficient_of_radiative_flux_in_sea_water", + "id": "volume_scattering_coefficient_of_radiative_flux_in_sea_water", "type": "standard_name", "name": "volume_scattering_coefficient_of_radiative_flux_in_sea_water", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Scattering of radiation is its deflection from its incident path without loss of energy. The (range of) direction(s) of scattering can be specified by a coordinate of scattering_angle.", diff --git a/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json b/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json index 4f985d5a2..55a447798 100644 --- a/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json +++ b/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", + "id": "volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "type": "standard_name", "name": "volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. Scattering of radiation is its deflection from its incident path without loss of energy. The volume scattering function is the intensity (flux per unit solid angle) of scattered radiation per unit length of scattering medium, normalised by the incident radiation flux. The (range of) direction(s) of scattering can be specified by a coordinate of scattering_angle. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the scattering applies at specific wavelengths or frequencies. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Aerosol\" means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. \"Ambient_aerosol\" means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. \"Ambient aerosol particles\" are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles. To specify the relative humidity and temperature at which the quantity described by the standard name applies, provide scalar coordinate variables with standard names of \"relative_humidity\" and \"air_temperature\".", diff --git a/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_sea_water.json b/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_sea_water.json index 63ddde818..1302b5320 100644 --- a/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_sea_water.json +++ b/data_descriptors/standard_name/volume_scattering_function_of_radiative_flux_in_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/volume_scattering_function_of_radiative_flux_in_sea_water", + "id": "volume_scattering_function_of_radiative_flux_in_sea_water", "type": "standard_name", "name": "volume_scattering_function_of_radiative_flux_in_sea_water", "description": "Radiative flux is the sum of shortwave and longwave radiative fluxes. Scattering of radiation is its deflection from its incident path without loss of energy. The volume scattering function is the intensity (flux per unit solid angle) of scattered radiation per unit length of scattering medium, normalised by the incident radiation flux. The (range of) direction(s) of scattering can be specified by a coordinate of scattering_angle. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the scattering applies at specific wavelengths or frequencies.", diff --git a/data_descriptors/standard_name/water_evaporation_amount.json b/data_descriptors/standard_name/water_evaporation_amount.json index 854d89b1b..ad6328f99 100644 --- a/data_descriptors/standard_name/water_evaporation_amount.json +++ b/data_descriptors/standard_name/water_evaporation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_evaporation_amount", + "id": "water_evaporation_amount", "type": "standard_name", "name": "water_evaporation_amount", "description": "\"Amount\" means mass per unit area. \"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".)", diff --git a/data_descriptors/standard_name/water_evaporation_amount_from_canopy.json b/data_descriptors/standard_name/water_evaporation_amount_from_canopy.json index edfde8115..539b10ac2 100644 --- a/data_descriptors/standard_name/water_evaporation_amount_from_canopy.json +++ b/data_descriptors/standard_name/water_evaporation_amount_from_canopy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_evaporation_amount_from_canopy", + "id": "water_evaporation_amount_from_canopy", "type": "standard_name", "name": "water_evaporation_amount_from_canopy", "description": "\"Amount\" means mass per unit area. \"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) \"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier \"where_type\" was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", diff --git a/data_descriptors/standard_name/water_evaporation_flux_from_canopy.json b/data_descriptors/standard_name/water_evaporation_flux_from_canopy.json index 93732e82b..e64810426 100644 --- a/data_descriptors/standard_name/water_evaporation_flux_from_canopy.json +++ b/data_descriptors/standard_name/water_evaporation_flux_from_canopy.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_evaporation_flux_from_canopy", + "id": "water_evaporation_flux_from_canopy", "type": "standard_name", "name": "water_evaporation_flux_from_canopy", "description": "\"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.\"Canopy\" means the vegetative covering over a surface. The canopy is often considered to be the outer surfaces of the vegetation. Plant height and the distribution, orientation and shape of plant leaves within a canopy influence the atmospheric environment and many plant processes within the canopy. Reference: AMS Glossary http://glossary.ametsoc.org/wiki/Canopy.", diff --git a/data_descriptors/standard_name/water_evaporation_flux_from_soil.json b/data_descriptors/standard_name/water_evaporation_flux_from_soil.json index cb0601ef9..46ec86862 100644 --- a/data_descriptors/standard_name/water_evaporation_flux_from_soil.json +++ b/data_descriptors/standard_name/water_evaporation_flux_from_soil.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_evaporation_flux_from_soil", + "id": "water_evaporation_flux_from_soil", "type": "standard_name", "name": "water_evaporation_flux_from_soil", "description": "\"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_evapotranspiration_amount.json b/data_descriptors/standard_name/water_evapotranspiration_amount.json index c900cacd6..e8804de87 100644 --- a/data_descriptors/standard_name/water_evapotranspiration_amount.json +++ b/data_descriptors/standard_name/water_evapotranspiration_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_evapotranspiration_amount", + "id": "water_evapotranspiration_amount", "type": "standard_name", "name": "water_evapotranspiration_amount", "description": "\"Evapotranspiration\" means all water vapor fluxes into the atmosphere from the surface: liquid evaporation, sublimation, and transpiration. \"Amount\" means mass per unit area. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) Transpiration is the process by which liquid water in plant stomata is transferred as water vapor into the atmosphere. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/water_evapotranspiration_flux.json b/data_descriptors/standard_name/water_evapotranspiration_flux.json index 62304ed25..780bf8f0c 100644 --- a/data_descriptors/standard_name/water_evapotranspiration_flux.json +++ b/data_descriptors/standard_name/water_evapotranspiration_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_evapotranspiration_flux", + "id": "water_evapotranspiration_flux", "type": "standard_name", "name": "water_evapotranspiration_flux", "description": "Water means water in all phases. \"Evapotranspiration\" means all water vapor fluxes into the atmosphere from the surface: liquid evaporation, sublimation and transpiration. Evaporation is the conversion of liquid or solid into vapor. Transpiration is the process by which liquid water in plant stomata is transferred as water vapor into the atmosphere. (The conversion of solid alone into vapor is called \"sublimation\".) In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water.json b/data_descriptors/standard_name/water_flux_into_sea_water.json index 2fa05bcb5..0aa5cba10 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water", + "id": "water_flux_into_sea_water", "type": "standard_name", "name": "water_flux_into_sea_water", "description": "\"Water\" means water in all phases. The water flux into sea water is the freshwater entering as a result of precipitation, evaporation, river inflow, sea ice effects and water flux relaxation and correction (if applied). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_due_to_flux_adjustment.json b/data_descriptors/standard_name/water_flux_into_sea_water_due_to_flux_adjustment.json index 636d8acba..c18a3fdf8 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_due_to_flux_adjustment.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_due_to_flux_adjustment.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_due_to_flux_adjustment", + "id": "water_flux_into_sea_water_due_to_flux_adjustment", "type": "standard_name", "name": "water_flux_into_sea_water_due_to_flux_adjustment", "description": "\"Water\" means water in all phases. Flux correction is also called \"flux adjustment\". A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/water_flux_into_sea_water_due_to_sea_ice_thermodynamics.json index 927c83bb6..9575b0ecd 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_due_to_sea_ice_thermodynamics", + "id": "water_flux_into_sea_water_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "water_flux_into_sea_water_due_to_sea_ice_thermodynamics", "description": "The water flux into sea water is the freshwater entering as a result of precipitation, evaporation, river inflow, sea ice effects and water flux correction (if applied). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_due_to_surface_drainage.json b/data_descriptors/standard_name/water_flux_into_sea_water_due_to_surface_drainage.json index 8bb83a606..a7c13b8e0 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_due_to_surface_drainage.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_due_to_surface_drainage.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_due_to_surface_drainage", + "id": "water_flux_into_sea_water_due_to_surface_drainage", "type": "standard_name", "name": "water_flux_into_sea_water_due_to_surface_drainage", "description": "The water flux into the ocean is the freshwater entering the sea water as a result of precipitation, evaporation, river inflow, sea ice effects and water flux correction (if applied). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase \"due_to_\" process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Surface drainage\" refers to all melt water forming at the sea ice surface and subsequently running into the sea.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_from_icebergs.json b/data_descriptors/standard_name/water_flux_into_sea_water_from_icebergs.json index 2840b8fec..d91230549 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_from_icebergs.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_from_icebergs.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_from_icebergs", + "id": "water_flux_into_sea_water_from_icebergs", "type": "standard_name", "name": "water_flux_into_sea_water_from_icebergs", "description": "The water flux into sea water is the freshwater entering as a result of precipitation, evaporation, river inflow, sea ice effects and water flux correction (if applied). The water flux into sea water from icebergs is due to the melting of the iceberg. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_from_land_ice.json b/data_descriptors/standard_name/water_flux_into_sea_water_from_land_ice.json index f2b16c0e0..596b226d1 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_from_land_ice.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_from_land_ice.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_from_land_ice", + "id": "water_flux_into_sea_water_from_land_ice", "type": "standard_name", "name": "water_flux_into_sea_water_from_land_ice", "description": "\"Land ice\" means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The water flux into sea water from land ice is the freshwater entering the ocean as a result of runoff from the surface and base of the ice and melting from the ice shelf base and vertical ice front. For an area-average, the cell_methods attribute should be used to specify whether the average is over the area of the whole grid cell or the area of the ocean portion only.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers.json b/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers.json index 7a7f18383..9e9163473 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_from_rivers", + "id": "water_flux_into_sea_water_from_rivers", "type": "standard_name", "name": "water_flux_into_sea_water_from_rivers", "description": "\"Water\" means water in all phases. The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux.json b/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux.json index d59d44ae6..4076111a9 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux", + "id": "water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux", "type": "standard_name", "name": "water_flux_into_sea_water_from_rivers_and_surface_downward_water_flux", "description": "\"Water\" means water in all phases, including frozen i.e. ice and snow. The surface called \"surface\" means the lower boundary of the atmosphere. \"Downward\" indicates a vector component which is positive when directed downward (negative upward). The surface water flux is the result of precipitation and evaporation. The water flux into sea water is the freshwater entering as a result of precipitation, evaporation, river inflow, sea ice effects and water flux correction (if applied). The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models. \"River\" refers to water in the fluvial system (stream and floodplain). In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_into_sea_water_without_flux_correction.json b/data_descriptors/standard_name/water_flux_into_sea_water_without_flux_correction.json index 2ed79af32..0c95a33c8 100644 --- a/data_descriptors/standard_name/water_flux_into_sea_water_without_flux_correction.json +++ b/data_descriptors/standard_name/water_flux_into_sea_water_without_flux_correction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_into_sea_water_without_flux_correction", + "id": "water_flux_into_sea_water_without_flux_correction", "type": "standard_name", "name": "water_flux_into_sea_water_without_flux_correction", "description": "Water means water in all phases. The water_flux_into_sea_water_without_flux_correction is the freshwater entering as a result of precipitation, evaporation, river inflow and sea ice effects. The total water flux including any flux relaxation(s) or correction(s) is described by the standard name water_flux_into_sea_water. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_out_of_sea_ice_and_sea_water.json b/data_descriptors/standard_name/water_flux_out_of_sea_ice_and_sea_water.json index f56f79a91..183bcf031 100644 --- a/data_descriptors/standard_name/water_flux_out_of_sea_ice_and_sea_water.json +++ b/data_descriptors/standard_name/water_flux_out_of_sea_ice_and_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_out_of_sea_ice_and_sea_water", + "id": "water_flux_out_of_sea_ice_and_sea_water", "type": "standard_name", "name": "water_flux_out_of_sea_ice_and_sea_water", "description": "\"Water\" means water in all phases. The water_flux_out_of_sea_ice_and_sea_water is the freshwater leaving the ocean as a result of precipitation, evaporation, river outflow and any water flux relaxation(s) and correction(s) that may have been applied. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. \"Sea ice\" means all ice floating in the sea which has formed from freezing sea water, rather than by other processes such as calving of land ice to form icebergs.", diff --git a/data_descriptors/standard_name/water_flux_out_of_sea_water.json b/data_descriptors/standard_name/water_flux_out_of_sea_water.json index 27efdf1ee..d8b0985aa 100644 --- a/data_descriptors/standard_name/water_flux_out_of_sea_water.json +++ b/data_descriptors/standard_name/water_flux_out_of_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_out_of_sea_water", + "id": "water_flux_out_of_sea_water", "type": "standard_name", "name": "water_flux_out_of_sea_water", "description": "The quantity water_flux_out_of_sea_water is the quantity with standard name water_flux_into_sea_water multiplied by -1. \"Water\" means water in all phases. The water flux out of sea water is the freshwater leaving as a result of precipitation, evaporation, river outflow, sea-ice and any water flux relaxation(s) and correction(s) that may have been applied. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_newtonian_relaxation.json b/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_newtonian_relaxation.json index 6a80601f2..034032257 100644 --- a/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_newtonian_relaxation.json +++ b/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_newtonian_relaxation.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_out_of_sea_water_due_to_newtonian_relaxation", + "id": "water_flux_out_of_sea_water_due_to_newtonian_relaxation", "type": "standard_name", "name": "water_flux_out_of_sea_water_due_to_newtonian_relaxation", "description": "The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. The water_flux_out_of_sea_water_due_to_newtonian_relaxation is the freshwater leaving as a result of the Newtonian relaxation of the sea surface salinity. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics.json b/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics.json index 1431566b0..c8b0261c4 100644 --- a/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics.json +++ b/data_descriptors/standard_name/water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics", + "id": "water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics", "type": "standard_name", "name": "water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics", "description": "The water flux out of sea water is the freshwater leaving the sea water. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. \"Sea ice thermodynamics\" refers to the addition or subtraction of sea ice mass due to surface and basal fluxes, i.e. due to melting, sublimation and fusion.", diff --git a/data_descriptors/standard_name/water_potential_evaporation_amount.json b/data_descriptors/standard_name/water_potential_evaporation_amount.json index 27afd1afb..30bceb859 100644 --- a/data_descriptors/standard_name/water_potential_evaporation_amount.json +++ b/data_descriptors/standard_name/water_potential_evaporation_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_potential_evaporation_amount", + "id": "water_potential_evaporation_amount", "type": "standard_name", "name": "water_potential_evaporation_amount", "description": "\"Amount\" means mass per unit area. \"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) Potential evaporation is the rate at which evaporation would take place under unaltered ambient conditions (temperature, relative humidity, wind, etc.) if the supply of water were unlimited, as if from an open water surface.", diff --git a/data_descriptors/standard_name/water_potential_evaporation_flux.json b/data_descriptors/standard_name/water_potential_evaporation_flux.json index 12e84c29b..617907317 100644 --- a/data_descriptors/standard_name/water_potential_evaporation_flux.json +++ b/data_descriptors/standard_name/water_potential_evaporation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_potential_evaporation_flux", + "id": "water_potential_evaporation_flux", "type": "standard_name", "name": "water_potential_evaporation_flux", "description": "\"Water\" means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\".) Potential evaporation is the rate at which evaporation would take place under unaltered ambient conditions (temperature, relative humidity, wind, etc.) if the supply of water were unlimited, as if from an open water surface. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_potential_evapotranspiration_amount.json b/data_descriptors/standard_name/water_potential_evapotranspiration_amount.json index 3da5a9cba..e4c16c65f 100644 --- a/data_descriptors/standard_name/water_potential_evapotranspiration_amount.json +++ b/data_descriptors/standard_name/water_potential_evapotranspiration_amount.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_potential_evapotranspiration_amount", + "id": "water_potential_evapotranspiration_amount", "type": "standard_name", "name": "water_potential_evapotranspiration_amount", "description": "Potential evapotranspiration is the rate at which evapotranspiration would occur under ambient conditions from a uniformly vegetated area when the water supply is not limiting. \"Evapotranspiration\" means all water vapor fluxes into the atmosphere from the surface: liquid evaporation, sublimation and transpiration. Transpiration is the process by which liquid water in plant stomata is transferred as water vapor into the atmosphere. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called \"sublimation\"). Amount means mass per unit area.", diff --git a/data_descriptors/standard_name/water_sublimation_flux.json b/data_descriptors/standard_name/water_sublimation_flux.json index 38c436507..9f7a7c20f 100644 --- a/data_descriptors/standard_name/water_sublimation_flux.json +++ b/data_descriptors/standard_name/water_sublimation_flux.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_sublimation_flux", + "id": "water_sublimation_flux", "type": "standard_name", "name": "water_sublimation_flux", "description": "\"Water\" means water in all phases. Sublimation is the conversion of solid into vapor. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/water_surface_height_above_reference_datum.json b/data_descriptors/standard_name/water_surface_height_above_reference_datum.json index fd43c0368..091d6c2a3 100644 --- a/data_descriptors/standard_name/water_surface_height_above_reference_datum.json +++ b/data_descriptors/standard_name/water_surface_height_above_reference_datum.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_surface_height_above_reference_datum", + "id": "water_surface_height_above_reference_datum", "type": "standard_name", "name": "water_surface_height_above_reference_datum", "description": "'Water surface height above reference datum' means the height of the upper surface of a body of liquid water, such as sea, lake or river, above an arbitrary reference datum. The altitude of the datum should be provided in a variable with standard name water_surface_reference_datum_altitude. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/water_surface_reference_datum_altitude.json b/data_descriptors/standard_name/water_surface_reference_datum_altitude.json index 5be748bbc..eb40f8ff1 100644 --- a/data_descriptors/standard_name/water_surface_reference_datum_altitude.json +++ b/data_descriptors/standard_name/water_surface_reference_datum_altitude.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_surface_reference_datum_altitude", + "id": "water_surface_reference_datum_altitude", "type": "standard_name", "name": "water_surface_reference_datum_altitude", "description": "Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. 'Water surface reference datum altitude' means the altitude of the arbitrary datum referred to by a quantity with standard name 'water_surface_height_above_reference_datum'. The surface called \"surface\" means the lower boundary of the atmosphere.", diff --git a/data_descriptors/standard_name/water_table_depth.json b/data_descriptors/standard_name/water_table_depth.json index 4f38d72b6..71d8864fd 100644 --- a/data_descriptors/standard_name/water_table_depth.json +++ b/data_descriptors/standard_name/water_table_depth.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_table_depth", + "id": "water_table_depth", "type": "standard_name", "name": "water_table_depth", "description": "Depth is the vertical distance below the surface. The water table is the surface below which the soil is saturated with water such that all pore spaces are filled.", diff --git a/data_descriptors/standard_name/water_vapor_partial_pressure_in_air.json b/data_descriptors/standard_name/water_vapor_partial_pressure_in_air.json index a10b10725..59c4dae9a 100644 --- a/data_descriptors/standard_name/water_vapor_partial_pressure_in_air.json +++ b/data_descriptors/standard_name/water_vapor_partial_pressure_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_vapor_partial_pressure_in_air", + "id": "water_vapor_partial_pressure_in_air", "type": "standard_name", "name": "water_vapor_partial_pressure_in_air", "description": "The partial pressure of a gaseous constituent of air is the pressure that it would exert if all other gaseous constituents were removed, assuming the volume, the temperature, and its number of moles remain unchanged.", diff --git a/data_descriptors/standard_name/water_vapor_saturation_deficit_in_air.json b/data_descriptors/standard_name/water_vapor_saturation_deficit_in_air.json index d550f3578..8047f4917 100644 --- a/data_descriptors/standard_name/water_vapor_saturation_deficit_in_air.json +++ b/data_descriptors/standard_name/water_vapor_saturation_deficit_in_air.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_vapor_saturation_deficit_in_air", + "id": "water_vapor_saturation_deficit_in_air", "type": "standard_name", "name": "water_vapor_saturation_deficit_in_air", "description": "\"Water vapor saturation deficit\" is the difference between the saturation water vapor partial pressure and the actual water vapor partial pressure in air.", diff --git a/data_descriptors/standard_name/water_volume_transport_in_river_channel.json b/data_descriptors/standard_name/water_volume_transport_in_river_channel.json index ae8c74c76..0c990ab08 100644 --- a/data_descriptors/standard_name/water_volume_transport_in_river_channel.json +++ b/data_descriptors/standard_name/water_volume_transport_in_river_channel.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_volume_transport_in_river_channel", + "id": "water_volume_transport_in_river_channel", "type": "standard_name", "name": "water_volume_transport_in_river_channel", "description": "The water flux or volume transport in rivers is the amount of water flowing in the river channel and flood plain. \"Water\" means water in all phases.", diff --git a/data_descriptors/standard_name/water_volume_transport_into_sea_water_from_rivers.json b/data_descriptors/standard_name/water_volume_transport_into_sea_water_from_rivers.json index f87fd3f6d..4347691f8 100644 --- a/data_descriptors/standard_name/water_volume_transport_into_sea_water_from_rivers.json +++ b/data_descriptors/standard_name/water_volume_transport_into_sea_water_from_rivers.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/water_volume_transport_into_sea_water_from_rivers", + "id": "water_volume_transport_into_sea_water_from_rivers", "type": "standard_name", "name": "water_volume_transport_into_sea_water_from_rivers", "description": "\"Water\" means water in all phases. The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models. \"River\" refers to water in the fluvial system (stream and floodplain).", diff --git a/data_descriptors/standard_name/wave_frequency.json b/data_descriptors/standard_name/wave_frequency.json index 18e6ca57f..0608d0c27 100644 --- a/data_descriptors/standard_name/wave_frequency.json +++ b/data_descriptors/standard_name/wave_frequency.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wave_frequency", + "id": "wave_frequency", "type": "standard_name", "name": "wave_frequency", "description": "Frequency is the number of oscillations of a wave per unit time.", diff --git a/data_descriptors/standard_name/westward_upward_derivative_of_geopotential.json b/data_descriptors/standard_name/westward_upward_derivative_of_geopotential.json index 20023c9d9..f11440c04 100644 --- a/data_descriptors/standard_name/westward_upward_derivative_of_geopotential.json +++ b/data_descriptors/standard_name/westward_upward_derivative_of_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/westward_upward_derivative_of_geopotential", + "id": "westward_upward_derivative_of_geopotential", "type": "standard_name", "name": "westward_upward_derivative_of_geopotential", "description": "A quantity with standard name Xward_Yward_derivative_of_geopotential is a second spatial derivative of geopotential, P, in the direction specified by X and Y, i.e., d2P/dXdY. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. \"Westward\" indicates a vector component which is positive when directed westward (negative eastward). \"Upward\" indicates a vector component which is positive when directed upward (negative downward). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude.", diff --git a/data_descriptors/standard_name/westward_westward_derivative_of_geopotential.json b/data_descriptors/standard_name/westward_westward_derivative_of_geopotential.json index 1967e5c84..f8158b0f4 100644 --- a/data_descriptors/standard_name/westward_westward_derivative_of_geopotential.json +++ b/data_descriptors/standard_name/westward_westward_derivative_of_geopotential.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/westward_westward_derivative_of_geopotential", + "id": "westward_westward_derivative_of_geopotential", "type": "standard_name", "name": "westward_westward_derivative_of_geopotential", "description": "A quantity with standard name Xward_Yward_derivative_of_geopotential is a second spatial derivative of geopotential, P, in the direction specified by X and Y, i.e., d2P/dXdY. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. \"Westward\" indicates a vector component which is positive when directed westward (negative eastward). \"component_derivative_of_X\" means derivative of X with respect to distance in the component direction, which may be \"northward\", \"southward\", \"eastward\", \"westward\", \"x\" or \"y\". The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude.", diff --git a/data_descriptors/standard_name/wet_bulb_potential_temperature.json b/data_descriptors/standard_name/wet_bulb_potential_temperature.json index a63a3df83..963055f2d 100644 --- a/data_descriptors/standard_name/wet_bulb_potential_temperature.json +++ b/data_descriptors/standard_name/wet_bulb_potential_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wet_bulb_potential_temperature", + "id": "wet_bulb_potential_temperature", "type": "standard_name", "name": "wet_bulb_potential_temperature", "description": "Wet bulb potential temperature is the temperature a parcel of air would have if moved dry adiabatically until it reaches saturation and thereafter moist adiabatically to sea level pressure. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/wet_bulb_temperature.json b/data_descriptors/standard_name/wet_bulb_temperature.json index 3d2bb70ca..466629324 100644 --- a/data_descriptors/standard_name/wet_bulb_temperature.json +++ b/data_descriptors/standard_name/wet_bulb_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wet_bulb_temperature", + "id": "wet_bulb_temperature", "type": "standard_name", "name": "wet_bulb_temperature", "description": "It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/wind_chill_of_air_temperature.json b/data_descriptors/standard_name/wind_chill_of_air_temperature.json index 5e2d13117..a319b3b1d 100644 --- a/data_descriptors/standard_name/wind_chill_of_air_temperature.json +++ b/data_descriptors/standard_name/wind_chill_of_air_temperature.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_chill_of_air_temperature", + "id": "wind_chill_of_air_temperature", "type": "standard_name", "name": "wind_chill_of_air_temperature", "description": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The quantity with standard name wind_chill_of_air_temperature is the perceived air temperature when wind is factored in with the ambient air temperature (which makes it feel colder than the actual air temperature). Wind chill is based on the rate of heat loss from exposed skin caused by wind and cold. Wind chill temperature is only defined for ambient temperatures at or below 283.1 K and wind speeds above 1.34 m s-1. References: https://www.weather.gov/safety/cold-wind-chill-chart; WMO codes registry entry http://codes.wmo.int/grib2/codeflag/4.2/0-0-13. It is strongly recommended that a variable with this standard name should have a units_metadata attribute, with one of the values \"on-scale\" or \"difference\", whichever is appropriate for the data, because it is essential to know whether the temperature is on-scale (meaning relative to the origin of the scale indicated by the units) or refers to temperature differences (implying that the origin of the temperature scale is irrevelant), in order to convert the units correctly (cf. https://cfconventions.org/cf-conventions/cf-conventions.html#temperature-units).", diff --git a/data_descriptors/standard_name/wind_from_direction.json b/data_descriptors/standard_name/wind_from_direction.json index 0d921afb6..676ccc3fd 100644 --- a/data_descriptors/standard_name/wind_from_direction.json +++ b/data_descriptors/standard_name/wind_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_from_direction", + "id": "wind_from_direction", "type": "standard_name", "name": "wind_from_direction", "description": "Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (wind_from_direction) (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (wind_to_direction) (eastward, southward, etc.) \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming.", diff --git a/data_descriptors/standard_name/wind_gust_from_direction.json b/data_descriptors/standard_name/wind_gust_from_direction.json index 64a1c35f7..243812058 100644 --- a/data_descriptors/standard_name/wind_gust_from_direction.json +++ b/data_descriptors/standard_name/wind_gust_from_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_gust_from_direction", + "id": "wind_gust_from_direction", "type": "standard_name", "name": "wind_gust_from_direction", "description": "The phrase \"from_direction\" is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north. A gust is a sudden brief period of high wind speed. In an observed time series of wind speed, the gust wind speed can be indicated by a cell_methods of \"maximum\" for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name \"upward_air_velocity\".) In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (\"wind_from_direction\") (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (\"wind_to_direction\") (eastward, southward, etc.).", diff --git a/data_descriptors/standard_name/wind_mixing_energy_flux_into_sea_water.json b/data_descriptors/standard_name/wind_mixing_energy_flux_into_sea_water.json index 1d8ad0668..03bde1b0e 100644 --- a/data_descriptors/standard_name/wind_mixing_energy_flux_into_sea_water.json +++ b/data_descriptors/standard_name/wind_mixing_energy_flux_into_sea_water.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_mixing_energy_flux_into_sea_water", + "id": "wind_mixing_energy_flux_into_sea_water", "type": "standard_name", "name": "wind_mixing_energy_flux_into_sea_water", "description": "Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/wind_speed.json b/data_descriptors/standard_name/wind_speed.json index 0f2a45083..bfc6c005d 100644 --- a/data_descriptors/standard_name/wind_speed.json +++ b/data_descriptors/standard_name/wind_speed.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_speed", + "id": "wind_speed", "type": "standard_name", "name": "wind_speed", "description": "Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity.", diff --git a/data_descriptors/standard_name/wind_speed_of_gust.json b/data_descriptors/standard_name/wind_speed_of_gust.json index c885df5db..353f899d9 100644 --- a/data_descriptors/standard_name/wind_speed_of_gust.json +++ b/data_descriptors/standard_name/wind_speed_of_gust.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_speed_of_gust", + "id": "wind_speed_of_gust", "type": "standard_name", "name": "wind_speed_of_gust", "description": "Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. A gust is a sudden brief period of high wind speed. In an observed timeseries of wind speed, the gust wind speed can be indicated by a cell_methods of maximum for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed.", diff --git a/data_descriptors/standard_name/wind_speed_of_gust_due_to_convection.json b/data_descriptors/standard_name/wind_speed_of_gust_due_to_convection.json index 3052fa571..0c3b1c300 100644 --- a/data_descriptors/standard_name/wind_speed_of_gust_due_to_convection.json +++ b/data_descriptors/standard_name/wind_speed_of_gust_due_to_convection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_speed_of_gust_due_to_convection", + "id": "wind_speed_of_gust_due_to_convection", "type": "standard_name", "name": "wind_speed_of_gust_due_to_convection", "description": "Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. A gust is a sudden brief period of high wind speed. In an observed timeseries of wind speed, the gust wind speed can be indicated by a cell_methods of maximum for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed. The specification of a physical process by the phrase \"due_to\" process means that the quantity named is a single term in a list of terms, the maximum of which composes the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/wind_speed_of_gust_due_to_turbulence.json b/data_descriptors/standard_name/wind_speed_of_gust_due_to_turbulence.json index fb628bb04..b405a006c 100644 --- a/data_descriptors/standard_name/wind_speed_of_gust_due_to_turbulence.json +++ b/data_descriptors/standard_name/wind_speed_of_gust_due_to_turbulence.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_speed_of_gust_due_to_turbulence", + "id": "wind_speed_of_gust_due_to_turbulence", "type": "standard_name", "name": "wind_speed_of_gust_due_to_turbulence", "description": "Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. A gust is a sudden brief period of high wind speed. In an observed timeseries of wind speed, the gust wind speed can be indicated by a cell_methods of maximum for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed. The specification of a physical process by the phrase \"due_to\" process means that the quantity named is a single term in a list of terms, the maximum of which composes the general quantity named by omitting the phrase.", diff --git a/data_descriptors/standard_name/wind_speed_shear.json b/data_descriptors/standard_name/wind_speed_shear.json index ee3da402f..d9d3a4d9e 100644 --- a/data_descriptors/standard_name/wind_speed_shear.json +++ b/data_descriptors/standard_name/wind_speed_shear.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_speed_shear", + "id": "wind_speed_shear", "type": "standard_name", "name": "wind_speed_shear", "description": "Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. Wind speed shear is the derivative of wind speed with respect to height.", diff --git a/data_descriptors/standard_name/wind_to_direction.json b/data_descriptors/standard_name/wind_to_direction.json index a035abbe1..f629670b6 100644 --- a/data_descriptors/standard_name/wind_to_direction.json +++ b/data_descriptors/standard_name/wind_to_direction.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wind_to_direction", + "id": "wind_to_direction", "type": "standard_name", "name": "wind_to_direction", "description": "Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (wind_from_direction) (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (wind_to_direction) (eastward, southward, etc.) \"to_direction\" is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed. The direction is a bearing in the usual geographical sense, measured positive clockwise from due north.", diff --git a/data_descriptors/standard_name/wood_debris_mass_content_of_carbon.json b/data_descriptors/standard_name/wood_debris_mass_content_of_carbon.json index de5a2572e..634af8090 100644 --- a/data_descriptors/standard_name/wood_debris_mass_content_of_carbon.json +++ b/data_descriptors/standard_name/wood_debris_mass_content_of_carbon.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wood_debris_mass_content_of_carbon", + "id": "wood_debris_mass_content_of_carbon", "type": "standard_name", "name": "wood_debris_mass_content_of_carbon", "description": "\"Content\" indicates a quantity per unit area. \"Wood debris\" means dead organic matter composed of coarse wood. It is distinct from fine litter. The precise distinction between \"fine\" and \"coarse\" is model dependent.", diff --git a/data_descriptors/standard_name/wood_debris_mass_content_of_nitrogen.json b/data_descriptors/standard_name/wood_debris_mass_content_of_nitrogen.json index 6bbd09f34..b5b829744 100644 --- a/data_descriptors/standard_name/wood_debris_mass_content_of_nitrogen.json +++ b/data_descriptors/standard_name/wood_debris_mass_content_of_nitrogen.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/wood_debris_mass_content_of_nitrogen", + "id": "wood_debris_mass_content_of_nitrogen", "type": "standard_name", "name": "wood_debris_mass_content_of_nitrogen", "description": "\"Content\" indicates a quantity per unit area. \"Wood debris\" means dead organic matter composed of coarse wood. It is distinct from fine litter. The precise distinction between \"fine\" and \"coarse\" is model dependent. The sum of the quantities with standard names wood_debris_mass_content_of_nitrogen, surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen is the total nitrogen mass content of dead plant material.", diff --git a/data_descriptors/standard_name/x_derivative_of_ocean_rigid_lid_pressure.json b/data_descriptors/standard_name/x_derivative_of_ocean_rigid_lid_pressure.json index b409ab3a7..00b09389a 100644 --- a/data_descriptors/standard_name/x_derivative_of_ocean_rigid_lid_pressure.json +++ b/data_descriptors/standard_name/x_derivative_of_ocean_rigid_lid_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/x_derivative_of_ocean_rigid_lid_pressure", + "id": "x_derivative_of_ocean_rigid_lid_pressure", "type": "standard_name", "name": "x_derivative_of_ocean_rigid_lid_pressure", "description": "\"component_derivative_of_X\" means the derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, whether or not they are true longitude and latitude. x_derivative_of_ocean_rigid_lid_pressure means (d/dx) of the ocean surface pressure, as derived by a rigid lid approximation, keeping the other horizontal coordinate (y, presumably) constant.", diff --git a/data_descriptors/standard_name/x_heat_flux_in_sea_water_due_to_advection.json b/data_descriptors/standard_name/x_heat_flux_in_sea_water_due_to_advection.json index 2052f2c34..448a3b938 100644 --- a/data_descriptors/standard_name/x_heat_flux_in_sea_water_due_to_advection.json +++ b/data_descriptors/standard_name/x_heat_flux_in_sea_water_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/x_heat_flux_in_sea_water_due_to_advection", + "id": "x_heat_flux_in_sea_water_due_to_advection", "type": "standard_name", "name": "x_heat_flux_in_sea_water_due_to_advection", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/x_wind.json b/data_descriptors/standard_name/x_wind.json index d87b87bf2..713d17ea2 100644 --- a/data_descriptors/standard_name/x_wind.json +++ b/data_descriptors/standard_name/x_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/x_wind", + "id": "x_wind", "type": "standard_name", "name": "x_wind", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/x_wind_gust.json b/data_descriptors/standard_name/x_wind_gust.json index cdba58f24..4d2f35aac 100644 --- a/data_descriptors/standard_name/x_wind_gust.json +++ b/data_descriptors/standard_name/x_wind_gust.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/x_wind_gust", + "id": "x_wind_gust", "type": "standard_name", "name": "x_wind_gust", "description": "\"x\" indicates a vector component along the grid x-axis, positive with increasing x. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) A gust is a sudden brief period of high wind speed. In an observed timeseries of wind speed, the gust wind speed can be indicated by a cell_methods of maximum for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed.", diff --git a/data_descriptors/standard_name/y_derivative_of_ocean_rigid_lid_pressure.json b/data_descriptors/standard_name/y_derivative_of_ocean_rigid_lid_pressure.json index 5a8883f32..ffc4c2a0e 100644 --- a/data_descriptors/standard_name/y_derivative_of_ocean_rigid_lid_pressure.json +++ b/data_descriptors/standard_name/y_derivative_of_ocean_rigid_lid_pressure.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/y_derivative_of_ocean_rigid_lid_pressure", + "id": "y_derivative_of_ocean_rigid_lid_pressure", "type": "standard_name", "name": "y_derivative_of_ocean_rigid_lid_pressure", "description": "\"component_derivative_of_X\" means the derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, whether or not they are true longitude and latitude. y_derivative_of_ocean_rigid_lid_pressure means (d/dy) of the ocean surface pressure, as derived by a rigid lid approximation, keeping the other horizontal coordinate (x, presumably) constant.", diff --git a/data_descriptors/standard_name/y_heat_flux_in_sea_water_due_to_advection.json b/data_descriptors/standard_name/y_heat_flux_in_sea_water_due_to_advection.json index b7ec7988c..1f56f0597 100644 --- a/data_descriptors/standard_name/y_heat_flux_in_sea_water_due_to_advection.json +++ b/data_descriptors/standard_name/y_heat_flux_in_sea_water_due_to_advection.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/y_heat_flux_in_sea_water_due_to_advection", + "id": "y_heat_flux_in_sea_water_due_to_advection", "type": "standard_name", "name": "y_heat_flux_in_sea_water_due_to_advection", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. In accordance with common usage in geophysical disciplines, \"flux\" implies per unit area, called \"flux density\" in physics.", diff --git a/data_descriptors/standard_name/y_wind.json b/data_descriptors/standard_name/y_wind.json index 47bf60d20..3276f1cc5 100644 --- a/data_descriptors/standard_name/y_wind.json +++ b/data_descriptors/standard_name/y_wind.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/y_wind", + "id": "y_wind", "type": "standard_name", "name": "y_wind", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)", diff --git a/data_descriptors/standard_name/y_wind_gust.json b/data_descriptors/standard_name/y_wind_gust.json index 9f99d8060..d50c1fa0f 100644 --- a/data_descriptors/standard_name/y_wind_gust.json +++ b/data_descriptors/standard_name/y_wind_gust.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/y_wind_gust", + "id": "y_wind_gust", "type": "standard_name", "name": "y_wind_gust", "description": "\"y\" indicates a vector component along the grid y-axis, positive with increasing y. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) A gust is a sudden brief period of high wind speed. In an observed time series of wind speed, the gust wind speed can be indicated by a cell_methods of maximum for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed.", diff --git a/data_descriptors/standard_name/zenith_angle.json b/data_descriptors/standard_name/zenith_angle.json index bda2a1202..43c3efa3f 100644 --- a/data_descriptors/standard_name/zenith_angle.json +++ b/data_descriptors/standard_name/zenith_angle.json @@ -1,6 +1,6 @@ { "@context": "_context_", - "id": "standard_name/zenith_angle", + "id": "zenith_angle", "type": "standard_name", "name": "zenith_angle", "description": "Zenith angle is the angle to the local vertical; a value of zero is directly overhead.",