From 6b3720cf41b278022be46f3e82db9a8a91154522 Mon Sep 17 00:00:00 2001 From: alperaltuntas Date: Sat, 27 Jul 2024 08:12:03 -0600 Subject: [PATCH] (1/2) Add separate fluxes for glc runoff. (2/2) Add heat content fields for lrunoff_glc and frunoff_glc. --- config_src/drivers/nuopc_cap/mom_cap.F90 | 24 +- .../drivers/nuopc_cap/mom_cap_methods.F90 | 17 ++ .../nuopc_cap/mom_surface_forcing_nuopc.F90 | 22 +- src/core/MOM_forcing_type.F90 | 234 ++++++++++++++---- src/diagnostics/MOM_sum_output.F90 | 4 +- .../vertical/MOM_bulk_mixed_layer.F90 | 6 +- .../vertical/MOM_diabatic_aux.F90 | 3 +- 7 files changed, 256 insertions(+), 54 deletions(-) diff --git a/config_src/drivers/nuopc_cap/mom_cap.F90 b/config_src/drivers/nuopc_cap/mom_cap.F90 index ba380afeaa..62386fc3ef 100644 --- a/config_src/drivers/nuopc_cap/mom_cap.F90 +++ b/config_src/drivers/nuopc_cap/mom_cap.F90 @@ -713,7 +713,9 @@ subroutine InitializeAdvertise(gcomp, importState, exportState, clock, rc) Ice_ocean_boundary% hevap (isc:iec,jsc:jec), & Ice_ocean_boundary% hcond (isc:iec,jsc:jec), & Ice_ocean_boundary% lrunoff_glc (isc:iec,jsc:jec), & - Ice_ocean_boundary% frunoff_glc (isc:iec,jsc:jec)) + Ice_ocean_boundary% frunoff_glc (isc:iec,jsc:jec), & + Ice_ocean_boundary% hrofl_glc (isc:iec,jsc:jec), & + Ice_ocean_boundary% hrofi_glc (isc:iec,jsc:jec)) Ice_ocean_boundary%hrain = 0.0 Ice_ocean_boundary%hsnow = 0.0 @@ -723,6 +725,8 @@ subroutine InitializeAdvertise(gcomp, importState, exportState, clock, rc) Ice_ocean_boundary%hcond = 0.0 Ice_ocean_boundary%lrunoff_glc = 0.0 Ice_ocean_boundary%frunoff_glc = 0.0 + Ice_ocean_boundary%hrofl_glc = 0.0 + Ice_ocean_boundary%hrofi_glc = 0.0 endif call query_ocean_state(ocean_state, use_waves=use_waves, wave_method=wave_method) @@ -783,6 +787,10 @@ subroutine InitializeAdvertise(gcomp, importState, exportState, clock, rc) call fld_list_add(fldsToOcn_num, fldsToOcn, "Foxx_hcond" , "will provide") call fld_list_add(fldsToOcn_num, fldsToOcn, "Foxx_hrofl" , "will provide") call fld_list_add(fldsToOcn_num, fldsToOcn, "Foxx_hrofi" , "will provide") + if (cesm_coupled) then + call fld_list_add(fldsToOcn_num, fldsToOcn, "Foxx_hrofl_glc" , "will provide") + call fld_list_add(fldsToOcn_num, fldsToOcn, "Foxx_hrofi_glc" , "will provide") + endif if (use_waves) then if (wave_method == "EFACTOR") then @@ -2789,6 +2797,20 @@ end subroutine shr_log_setLogUnit !! !! !! +!! Foxx_hrofi_glc +!! W m-2 +!! hrofi_glc +!! heat content (enthalpy) of frozen glc runoff +!! +!! +!! +!! Foxx_hrofl_glc +!! W m-2 +!! hrofl_glc +!! heat content (enthalpy) of liquid glc runoff +!! +!! +!! !! Fioi_salt !! kg m-2 s-1 !! salt_flux diff --git a/config_src/drivers/nuopc_cap/mom_cap_methods.F90 b/config_src/drivers/nuopc_cap/mom_cap_methods.F90 index 4206ad17a2..307462cc30 100644 --- a/config_src/drivers/nuopc_cap/mom_cap_methods.F90 +++ b/config_src/drivers/nuopc_cap/mom_cap_methods.F90 @@ -269,6 +269,23 @@ subroutine mom_import(ocean_public, ocean_grid, importState, ice_ocean_boundary, if (ChkErr(rc,__LINE__,u_FILE_u)) return end if + !---- + ! enthalpy from liquid glc runoff (hrofl_glc) + !---- + if ( associated(ice_ocean_boundary%hrofl_glc) ) then + call state_getimport(importState, 'Foxx_hrofl_glc', isc, iec, jsc, jec, & + ice_ocean_boundary%hrofl_glc, areacor=med2mod_areacor, rc=rc) + if (ChkErr(rc,__LINE__,u_FILE_u)) return + end if + + !---- + ! enthalpy from frozen glc runoff (hrofi_glc) + !---- + if ( associated(ice_ocean_boundary%hrofi_glc) ) then + call state_getimport(importState, 'Foxx_hrofi_glc', isc, iec, jsc, jec, & + ice_ocean_boundary%hrofi_glc, areacor=med2mod_areacor, rc=rc) + if (ChkErr(rc,__LINE__,u_FILE_u)) return + end if !---- ! enthalpy from evaporation (hevap) !---- diff --git a/config_src/drivers/nuopc_cap/mom_surface_forcing_nuopc.F90 b/config_src/drivers/nuopc_cap/mom_surface_forcing_nuopc.F90 index 292a7eb64d..5f2e186bd4 100644 --- a/config_src/drivers/nuopc_cap/mom_surface_forcing_nuopc.F90 +++ b/config_src/drivers/nuopc_cap/mom_surface_forcing_nuopc.F90 @@ -180,6 +180,8 @@ module MOM_surface_forcing_nuopc real, pointer, dimension(:,:) :: mass_berg =>NULL() !< mass of icebergs(kg/m2) real, pointer, dimension(:,:) :: hrofl =>NULL() !< heat content from liquid runoff [W/m2] real, pointer, dimension(:,:) :: hrofi =>NULL() !< heat content from frozen runoff [W/m2] + real, pointer, dimension(:,:) :: hrofl_glc =>NULL() !< heat content from liquid glc runoff [W/m2] + real, pointer, dimension(:,:) :: hrofi_glc =>NULL() !< heat content from frozen glc runoff [W/m2] real, pointer, dimension(:,:) :: hrain =>NULL() !< heat content from liquid precipitation [W/m2] real, pointer, dimension(:,:) :: hsnow =>NULL() !< heat content from frozen precipitation [W/m2] real, pointer, dimension(:,:) :: hevap =>NULL() !< heat content from evaporation [W/m2] @@ -476,12 +478,12 @@ subroutine convert_IOB_to_fluxes(IOB, fluxes, index_bounds, Time, valid_time, G, ! add liquid glc runoff flux via rof if (associated(IOB%lrunoff_glc)) then - fluxes%lrunoff(i,j) = fluxes%lrunoff(i,j) + kg_m2_s_conversion * IOB%lrunoff_glc(i-i0,j-j0) * G%mask2dT(i,j) + fluxes%lrunoff_glc(i,j) = kg_m2_s_conversion * IOB%lrunoff_glc(i-i0,j-j0) * G%mask2dT(i,j) endif ! ice glc runoff flux via rof if (associated(IOB%frunoff_glc)) then - fluxes%frunoff(i,j) = fluxes%frunoff(i,j) + kg_m2_s_conversion * IOB%frunoff_glc(i-i0,j-j0) * G%mask2dT(i,j) + fluxes%frunoff_glc(i,j) = kg_m2_s_conversion * IOB%frunoff_glc(i-i0,j-j0) * G%mask2dT(i,j) endif if (associated(IOB%ustar_berg)) & @@ -525,6 +527,7 @@ subroutine convert_IOB_to_fluxes(IOB, fluxes, index_bounds, Time, valid_time, G, if (associated(IOB%frunoff_glc)) then fluxes%latent(i,j) = fluxes%latent(i,j) - & IOB%frunoff_glc(i-i0,j-j0) * US%W_m2_to_QRZ_T * CS%latent_heat_fusion + ! todo: confirm below subtraction of frunoff_glc to latent_frunoff_diag is correct. fluxes%latent_frunoff_diag(i,j) = fluxes%latent_frunoff_diag(i,j) - G%mask2dT(i,j) * & IOB%frunoff_glc(i-i0,j-j0) * US%W_m2_to_QRZ_T * CS%latent_heat_fusion endif @@ -569,6 +572,12 @@ subroutine convert_IOB_to_fluxes(IOB, fluxes, index_bounds, Time, valid_time, G, if (associated(IOB%hcond)) & fluxes%heat_content_cond(i,j) = US%W_m2_to_QRZ_T * IOB%hcond(i-i0,j-j0) * G%mask2dT(i,j) + + if (associated(IOB%hrofl_glc)) & + fluxes%heat_content_lrunoff_glc(i,j) = US%W_m2_to_QRZ_T * IOB%hrofl_glc(i-i0,j-j0) * G%mask2dT(i,j) + + if (associated(IOB%hrofi_glc)) & + fluxes%heat_content_frunoff_glc(i,j) = US%W_m2_to_QRZ_T * IOB%hrofi_glc(i-i0,j-j0) * G%mask2dT(i,j) endif ! sea ice fraction [nondim] @@ -622,7 +631,8 @@ subroutine convert_IOB_to_fluxes(IOB, fluxes, index_bounds, Time, valid_time, G, do j=js,je ; do i=is,ie net_FW(i,j) = US%RZ_T_to_kg_m2s * & (((fluxes%lprec(i,j) + fluxes%fprec(i,j) + fluxes%seaice_melt(i,j)) + & - (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j))) + & + (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j) + & + fluxes%lrunoff_glc(i,j) + fluxes%frunoff_glc(i,j))) + & (fluxes%evap(i,j) + fluxes%vprec(i,j)) ) * US%L_to_m**2*G%areaT(i,j) net_FW2(i,j) = net_FW(i,j) / (US%L_to_m**2*G%areaT(i,j)) enddo ; enddo @@ -1536,6 +1546,12 @@ subroutine ice_ocn_bnd_type_chksum(id, timestep, iobt) if (associated(iobt%hcond)) then chks = field_chksum( iobt%hcond ) ; if (root) write(outunit,100) 'iobt%hcond ', chks endif + if (associated(iobt%hrofl_glc)) then + chks = field_chksum( iobt%hrofl_glc ) ; if (root) write(outunit,100) 'iobt%hrofl_glc ', chks + endif + if (associated(iobt%hrofl_glc)) then + chks = field_chksum( iobt%hrofl_glc ) ; if (root) write(outunit,100) 'iobt%hrofl_glc ', chks + endif 100 FORMAT(" CHECKSUM::",A20," = ",Z20) diff --git a/src/core/MOM_forcing_type.F90 b/src/core/MOM_forcing_type.F90 index b8b3174b4a..0060e62be9 100644 --- a/src/core/MOM_forcing_type.F90 +++ b/src/core/MOM_forcing_type.F90 @@ -119,6 +119,8 @@ module MOM_forcing_type vprec => NULL(), & !< virtual liquid precip associated w/ SSS restoring [R Z T-1 ~> kg m-2 s-1] lrunoff => NULL(), & !< liquid river runoff entering ocean [R Z T-1 ~> kg m-2 s-1] frunoff => NULL(), & !< frozen river runoff (calving) entering ocean [R Z T-1 ~> kg m-2 s-1] + lrunoff_glc => NULL(), & !< liquid river glc runoff entering ocean [R Z T-1 ~> kg m-2 s-1] + frunoff_glc => NULL(), & !< frozen river glc runoff entering ocean [R Z T-1 ~> kg m-2 s-1] seaice_melt => NULL() !< snow/seaice melt (positive) or formation (negative) [R Z T-1 ~> kg m-2 s-1] ! Integrated water mass fluxes into the ocean, used for passive tracer sources [H ~> m or kg m-2] @@ -131,15 +133,17 @@ module MOM_forcing_type ! heat associated with water crossing ocean surface real, pointer, dimension(:,:) :: & - heat_content_cond => NULL(), & !< heat content associated with condensating water [Q R Z T-1 ~> W m-2] - heat_content_evap => NULL(), & !< heat content associated with evaporating water [Q R Z T-1 ~> W m-2] - heat_content_lprec => NULL(), & !< heat content associated with liquid >0 precip [Q R Z T-1 ~> W m-2] - heat_content_fprec => NULL(), & !< heat content associated with frozen precip [Q R Z T-1 ~> W m-2] - heat_content_vprec => NULL(), & !< heat content associated with virtual >0 precip [Q R Z T-1 ~> W m-2] - heat_content_lrunoff => NULL(), & !< heat content associated with liquid runoff [Q R Z T-1 ~> W m-2] - heat_content_frunoff => NULL(), & !< heat content associated with frozen runoff [Q R Z T-1 ~> W m-2] - heat_content_massout => NULL(), & !< heat content associated with mass leaving ocean [Q R Z T-1 ~> W m-2] - heat_content_massin => NULL() !< heat content associated with mass entering ocean [Q R Z T-1 ~> W m-2] + heat_content_cond => NULL(), & !< heat content associated with condensating water [Q R Z T-1 ~> W m-2] + heat_content_evap => NULL(), & !< heat content associated with evaporating water [Q R Z T-1 ~> W m-2] + heat_content_lprec => NULL(), & !< heat content associated with liquid >0 precip [Q R Z T-1 ~> W m-2] + heat_content_fprec => NULL(), & !< heat content associated with frozen precip [Q R Z T-1 ~> W m-2] + heat_content_vprec => NULL(), & !< heat content associated with virtual >0 precip [Q R Z T-1 ~> W m-2] + heat_content_lrunoff => NULL(), & !< heat content associated with liquid runoff [Q R Z T-1 ~> W m-2] + heat_content_frunoff => NULL(), & !< heat content associated with frozen runoff [Q R Z T-1 ~> W m-2] + heat_content_lrunoff_glc => NULL(), & !< heat content associated with liquid runoff [Q R Z T-1 ~> W m-2] + heat_content_frunoff_glc => NULL(), & !< heat content associated with frozen runoff [Q R Z T-1 ~> W m-2] + heat_content_massout => NULL(), & !< heat content associated with mass leaving ocean [Q R Z T-1 ~> W m-2] + heat_content_massin => NULL() !< heat content associated with mass entering ocean [Q R Z T-1 ~> W m-2] ! salt mass flux (contributes to ocean mass only if non-Bouss ) real, pointer, dimension(:,:) :: & @@ -304,6 +308,7 @@ module MOM_forcing_type integer :: id_precip = -1, id_vprec = -1 integer :: id_lprec = -1, id_fprec = -1 integer :: id_lrunoff = -1, id_frunoff = -1 + integer :: id_lrunoff_glc = -1, id_frunoff_glc = -1 integer :: id_net_massout = -1, id_net_massin = -1 integer :: id_massout_flux = -1, id_massin_flux = -1 integer :: id_seaice_melt = -1 @@ -313,6 +318,7 @@ module MOM_forcing_type integer :: id_total_precip = -1, id_total_vprec = -1 integer :: id_total_lprec = -1, id_total_fprec = -1 integer :: id_total_lrunoff = -1, id_total_frunoff = -1 + integer :: id_total_lrunoff_glc = -1, id_total_frunoff_glc = -1 integer :: id_total_net_massout = -1, id_total_net_massin = -1 integer :: id_total_seaice_melt = -1 @@ -322,34 +328,35 @@ module MOM_forcing_type integer :: id_precip_ga = -1, id_vprec_ga= -1 ! heat flux diagnostic handles - integer :: id_net_heat_coupler = -1, id_net_heat_surface = -1 - integer :: id_sens = -1, id_LwLatSens = -1 - integer :: id_sw = -1, id_lw = -1 - integer :: id_sw_vis = -1, id_sw_nir = -1 - integer :: id_lat_evap = -1, id_lat_frunoff = -1 - integer :: id_lat = -1, id_lat_fprec = -1 - integer :: id_heat_content_lrunoff= -1, id_heat_content_frunoff = -1 - integer :: id_heat_content_lprec = -1, id_heat_content_fprec = -1 - integer :: id_heat_content_cond = -1, id_heat_content_surfwater= -1 - integer :: id_heat_content_evap = -1 - integer :: id_heat_content_vprec = -1, id_heat_content_massout = -1 - integer :: id_heat_added = -1, id_heat_content_massin = -1 - integer :: id_hfrainds = -1, id_hfrunoffds = -1 - integer :: id_seaice_melt_heat = -1 + integer :: id_net_heat_coupler = -1, id_net_heat_surface = -1 + integer :: id_sens = -1, id_LwLatSens = -1 + integer :: id_sw = -1, id_lw = -1 + integer :: id_sw_vis = -1, id_sw_nir = -1 + integer :: id_lat_evap = -1, id_lat_frunoff = -1 + integer :: id_lat = -1, id_lat_fprec = -1 + integer :: id_heat_content_lrunoff = -1, id_heat_content_frunoff = -1 + integer :: id_heat_content_lrunoff_glc= -1, id_heat_content_frunoff_glc= -1 + integer :: id_heat_content_lprec = -1, id_heat_content_fprec = -1 + integer :: id_heat_content_cond = -1, id_heat_content_surfwater = -1 + integer :: id_heat_content_evap = -1 + integer :: id_heat_content_vprec = -1, id_heat_content_massout = -1 + integer :: id_heat_added = -1, id_heat_content_massin = -1 + integer :: id_hfrainds = -1, id_hfrunoffds = -1 + integer :: id_seaice_melt_heat = -1 ! global area integrated heat flux diagnostic handles - integer :: id_total_net_heat_coupler = -1, id_total_net_heat_surface = -1 - integer :: id_total_sens = -1, id_total_LwLatSens = -1 - integer :: id_total_sw = -1, id_total_lw = -1 - integer :: id_total_lat_evap = -1, id_total_lat_frunoff = -1 - integer :: id_total_lat = -1, id_total_lat_fprec = -1 - integer :: id_total_heat_content_lrunoff= -1, id_total_heat_content_frunoff = -1 - integer :: id_total_heat_content_lprec = -1, id_total_heat_content_fprec = -1 - integer :: id_total_heat_content_cond = -1, id_total_heat_content_surfwater= -1 - integer :: id_total_heat_content_evap = -1 - integer :: id_total_heat_content_vprec = -1, id_total_heat_content_massout = -1 - integer :: id_total_heat_added = -1, id_total_heat_content_massin = -1 - integer :: id_total_seaice_melt_heat = -1 + integer :: id_total_net_heat_coupler = -1, id_total_net_heat_surface = -1 + integer :: id_total_sens = -1, id_total_LwLatSens = -1 + integer :: id_total_sw = -1, id_total_lw = -1 + integer :: id_total_lat_evap = -1, id_total_lat_frunoff = -1 + integer :: id_total_lat = -1, id_total_lat_fprec = -1 + integer :: id_total_heat_content_lrunoff = -1, id_total_heat_content_frunoff = -1 + integer :: id_total_heat_content_lprec = -1, id_total_heat_content_fprec = -1 + integer :: id_total_heat_content_cond = -1, id_total_heat_content_surfwater = -1 + integer :: id_total_heat_content_evap = -1 + integer :: id_total_heat_content_vprec = -1, id_total_heat_content_massout = -1 + integer :: id_total_heat_added = -1, id_total_heat_content_massin = -1 + integer :: id_total_seaice_melt_heat = -1 ! global area averaged heat flux diagnostic handles integer :: id_net_heat_coupler_ga = -1, id_net_heat_surface_ga = -1 @@ -590,23 +597,27 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & ! net volume/mass of liquid and solid passing through surface boundary fluxes netMassInOut(i) = dt * (scale * & - (((((( fluxes%lprec(i,j) & + ((((((( fluxes%lprec(i,j) & + fluxes%fprec(i,j) ) & + fluxes%evap(i,j) ) & + fluxes%lrunoff(i,j) ) & + + fluxes%lrunoff_glc(i,j)) & + fluxes%vprec(i,j) ) & + fluxes%seaice_melt(i,j)) & - + fluxes%frunoff(i,j) )) + + fluxes%frunoff(i,j) ) & + + fluxes%frunoff_glc(i,j)) if (do_NMIOr) then ! Repeat the above code without multiplying by a timestep for legacy reasons netMassInOut_rate(i) = (scale * & - (((((( fluxes%lprec(i,j) & + ((((((( fluxes%lprec(i,j) & + fluxes%fprec(i,j) ) & + fluxes%evap(i,j) ) & + fluxes%lrunoff(i,j) ) & + + fluxes%lrunoff_glc(i,j)) & + fluxes%vprec(i,j) ) & + fluxes%seaice_melt(i,j)) & - + fluxes%frunoff(i,j) )) + + fluxes%frunoff(i,j) ) & + + fluxes%frunoff_glc(i,j)) endif ! smg: @@ -681,6 +692,8 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & ! remove lrunoff*SST here, to counteract its addition elsewhere net_heat(i) = (net_heat(i) + (scale*(dt * I_Cp_Hconvert)) * fluxes%heat_content_lrunoff(i,j)) - & (GV%RZ_to_H * (scale * dt)) * fluxes%lrunoff(i,j) * T(i,1) + net_heat(i) = (net_heat(i) + (scale*(dt * I_Cp_Hconvert)) * fluxes%heat_content_lrunoff_glc(i,j)) - & + (GV%RZ_to_H * (scale * dt)) * fluxes%lrunoff_glc(i,j) * T(i,1) !BGR-Jul 5, 2017{ !Intentionally neglect the following contribution to rate for legacy reasons. !if (do_NHR) net_heat_rate(i) = (net_heat_rate(i) + (scale*I_Cp_Hconvert) * fluxes%heat_content_lrunoff(i,j)) - & @@ -689,6 +702,8 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & if (calculate_diags .and. associated(tv%TempxPmE)) then tv%TempxPmE(i,j) = tv%TempxPmE(i,j) + (scale * dt) * & (I_Cp*fluxes%heat_content_lrunoff(i,j) - fluxes%lrunoff(i,j)*T(i,1)) + tv%TempxPmE(i,j) = tv%TempxPmE(i,j) + (scale * dt) * & + (I_Cp*fluxes%heat_content_lrunoff_glc(i,j) - fluxes%lrunoff_glc(i,j)*T(i,1)) endif endif @@ -698,6 +713,8 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & ! remove frunoff*SST here, to counteract its addition elsewhere net_heat(i) = net_heat(i) + (scale*(dt * I_Cp_Hconvert)) * fluxes%heat_content_frunoff(i,j) - & (GV%RZ_to_H * (scale * dt)) * fluxes%frunoff(i,j) * T(i,1) + net_heat(i) = net_heat(i) + (scale*(dt * I_Cp_Hconvert)) * fluxes%heat_content_frunoff_glc(i,j) - & + (GV%RZ_to_H * (scale * dt)) * fluxes%frunoff_glc(i,j) * T(i,1) !BGR-Jul 5, 2017{ !Intentionally neglect the following contribution to rate for legacy reasons. ! if (do_NHR) net_heat_rate(i) = net_heat_rate(i) + (scale*I_Cp_Hconvert) * fluxes%heat_content_frunoff(i,j) - & @@ -706,6 +723,8 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & if (calculate_diags .and. associated(tv%TempxPmE)) then tv%TempxPmE(i,j) = tv%TempxPmE(i,j) + (scale * dt) * & (I_Cp*fluxes%heat_content_frunoff(i,j) - fluxes%frunoff(i,j)*T(i,1)) + tv%TempxPmE(i,j) = tv%TempxPmE(i,j) + (scale * dt) * & + (I_Cp*fluxes%heat_content_frunoff_glc(i,j) - fluxes%frunoff_glc(i,j)*T(i,1)) endif endif @@ -729,6 +748,7 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & if (.not. do_enthalpy) then net_heat(i) = net_heat(i) + (scale * dt * I_Cp_Hconvert * & (fluxes%heat_content_lrunoff(i,j) + fluxes%heat_content_frunoff(i,j) + & + fluxes%heat_content_lrunoff_glc(i,j) + fluxes%heat_content_frunoff_glc(i,j) + & fluxes%heat_content_lprec(i,j) + fluxes%heat_content_fprec(i,j) + & fluxes%heat_content_evap(i,j) + fluxes%heat_content_cond(i,j))) endif @@ -857,6 +877,9 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & if (associated(fluxes%lrunoff) .and. associated(fluxes%heat_content_lrunoff)) then fluxes%heat_content_lrunoff(i,j) = tv%C_p*fluxes%lrunoff(i,j)*T(i,1) endif + if (associated(fluxes%lrunoff_glc) .and. associated(fluxes%heat_content_lrunoff_glc)) then + fluxes%heat_content_lrunoff_glc(i,j) = tv%C_p*fluxes%lrunoff_glc(i,j)*T(i,1) + endif endif ! Icebergs enter ocean at SST if land model does not provide calving heat content. @@ -864,6 +887,9 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & if (associated(fluxes%frunoff) .and. associated(fluxes%heat_content_frunoff)) then fluxes%heat_content_frunoff(i,j) = tv%C_p*fluxes%frunoff(i,j)*T(i,1) endif + if (associated(fluxes%frunoff_glc) .and. associated(fluxes%heat_content_frunoff_glc)) then + fluxes%heat_content_frunoff_glc(i,j) = tv%C_p*fluxes%frunoff_glc(i,j)*T(i,1) + endif endif elseif (.not. do_enthalpy) then @@ -886,6 +912,8 @@ subroutine extractFluxes1d(G, GV, US, fluxes, optics, nsw, j, dt, & fluxes%heat_content_fprec(i,j) + & fluxes%heat_content_lrunoff(i,j) + & fluxes%heat_content_frunoff(i,j) + & + fluxes%heat_content_lrunoff_glc(i,j) + & + fluxes%heat_content_frunoff_glc(i,j) + & fluxes%heat_content_evap(i,j) + & fluxes%heat_content_cond(i,j)) endif @@ -1319,14 +1347,24 @@ subroutine MOM_forcing_chksum(mesg, fluxes, G, US, haloshift) call hchksum(fluxes%ustar_tidal, mesg//" fluxes%ustar_tidal", G%HI, haloshift=hshift, scale=US%Z_to_m*US%s_to_T) if (associated(fluxes%lrunoff)) & call hchksum(fluxes%lrunoff, mesg//" fluxes%lrunoff", G%HI, haloshift=hshift, scale=US%RZ_T_to_kg_m2s) + if (associated(fluxes%lrunoff_glc)) & + call hchksum(fluxes%lrunoff_glc, mesg//" fluxes%lrunoff_glc", G%HI, haloshift=hshift, scale=US%RZ_T_to_kg_m2s) if (associated(fluxes%frunoff)) & call hchksum(fluxes%frunoff, mesg//" fluxes%frunoff", G%HI, haloshift=hshift, scale=US%RZ_T_to_kg_m2s) + if (associated(fluxes%frunoff_glc)) & + call hchksum(fluxes%frunoff_glc, mesg//" fluxes%frunoff_glc", G%HI, haloshift=hshift, scale=US%RZ_T_to_kg_m2s) if (associated(fluxes%heat_content_lrunoff)) & call hchksum(fluxes%heat_content_lrunoff, mesg//" fluxes%heat_content_lrunoff", G%HI, & haloshift=hshift, scale=US%QRZ_T_to_W_m2) + if (associated(fluxes%heat_content_lrunoff_glc)) & + call hchksum(fluxes%heat_content_lrunoff_glc, mesg//" fluxes%heat_content_lrunoff_glc", G%HI, & + haloshift=hshift, scale=US%QRZ_T_to_W_m2) if (associated(fluxes%heat_content_frunoff)) & call hchksum(fluxes%heat_content_frunoff, mesg//" fluxes%heat_content_frunoff", G%HI, & haloshift=hshift, scale=US%QRZ_T_to_W_m2) + if (associated(fluxes%heat_content_frunoff_glc)) & + call hchksum(fluxes%heat_content_frunoff_glc, mesg//" fluxes%heat_content_frunoff_glc", G%HI, & + haloshift=hshift, scale=US%QRZ_T_to_W_m2) if (associated(fluxes%heat_content_lprec)) & call hchksum(fluxes%heat_content_lprec, mesg//" fluxes%heat_content_lprec", G%HI, & haloshift=hshift, scale=US%QRZ_T_to_W_m2) @@ -1441,9 +1479,13 @@ subroutine forcing_SinglePointPrint(fluxes, G, i, j, mesg) call locMsg(fluxes%TKE_tidal,'TKE_tidal') call locMsg(fluxes%ustar_tidal,'ustar_tidal') call locMsg(fluxes%lrunoff,'lrunoff') + call locMsg(fluxes%lrunoff_glc,'lrunoff_glc') call locMsg(fluxes%frunoff,'frunoff') + call locMsg(fluxes%frunoff_glc,'frunoff_glc') call locMsg(fluxes%heat_content_lrunoff,'heat_content_lrunoff') + call locMsg(fluxes%heat_content_lrunoff_glc,'heat_content_lrunoff_glc') call locMsg(fluxes%heat_content_frunoff,'heat_content_frunoff') + call locMsg(fluxes%heat_content_frunoff_glc,'heat_content_frunoff_glc') call locMsg(fluxes%heat_content_lprec,'heat_content_lprec') call locMsg(fluxes%heat_content_fprec,'heat_content_fprec') call locMsg(fluxes%heat_content_vprec,'heat_content_vprec') @@ -1608,6 +1650,12 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, cmor_standard_name='water_flux_into_sea_water_from_icebergs', & cmor_long_name='Water Flux into Seawater from Icebergs') + !todo: check if above ficeberg (only including frunoff) should include below frunoff_glc + handles%id_frunoff_glc = register_diag_field('ocean_model', 'frunoff_glc', diag%axesT1, Time, & + 'Frozen glc runoff (calving) and iceberg melt into ocean', & + units='kg m-2 s-1', conversion=US%RZ_T_to_kg_m2s, & + standard_name='glc_water_flux_into_sea_water_from_icebergs') + handles%id_lrunoff = register_diag_field('ocean_model', 'lrunoff', diag%axesT1, Time, & 'Liquid runoff (rivers) into ocean', & units='kg m-2 s-1', conversion=US%RZ_T_to_kg_m2s, & @@ -1615,6 +1663,12 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, cmor_standard_name='water_flux_into_sea_water_from_rivers', & cmor_long_name='Water Flux into Sea Water From Rivers') + !todo: check if above friver (only including lrunoff) should include below lrunoff_glc + handles%id_lrunoff_glc = register_diag_field('ocean_model', 'lrunoff_glc', diag%axesT1, Time, & + 'Liquid runoff (glaciers) into ocean', & + units='kg m-2 s-1', conversion=US%RZ_T_to_kg_m2s, & + standard_name='water_flux_into_sea_water_from_glaciers') + handles%id_net_massout = register_diag_field('ocean_model', 'net_massout', diag%axesT1, Time, & 'Net mass leaving the ocean due to evaporation, seaice formation', & 'kg m-2 s-1', conversion=US%RZ_T_to_kg_m2s) @@ -1682,12 +1736,18 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, cmor_standard_name='water_flux_into_sea_water_from_icebergs_area_integrated', & cmor_long_name='Water Flux into Seawater from Icebergs Area Integrated') + handles%id_total_frunoff_glc = register_scalar_field('ocean_model', 'total_frunoff_glc', Time, diag, & + long_name='Area integrated frozen glc runoff (calving) & iceberg melt into ocean', units='kg s-1') + handles%id_total_lrunoff = register_scalar_field('ocean_model', 'total_lrunoff', Time, diag,& long_name='Area integrated liquid runoff into ocean', units='kg s-1', & cmor_field_name='total_friver', & cmor_standard_name='water_flux_into_sea_water_from_rivers_area_integrated', & cmor_long_name='Water Flux into Sea Water From Rivers Area Integrated') + handles%id_total_lrunoff_glc = register_scalar_field('ocean_model', 'total_lrunoff_glc', Time, diag,& + long_name='Area integrated liquid glc runoff into ocean', units='kg s-1') + handles%id_total_net_massout = register_scalar_field('ocean_model', 'total_net_massout', Time, diag, & long_name='Area integrated mass leaving ocean due to evap and seaice form', units='kg s-1') @@ -1746,6 +1806,14 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, 'W m-2', conversion=US%QRZ_T_to_W_m2, & standard_name='temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water') + handles%id_heat_content_frunoff_glc = register_diag_field('ocean_model', 'heat_content_frunoff_glc', & + diag%axesT1, Time, 'Heat content (relative to 0C) of solid glc runoff into ocean', & + 'W m-2', conversion=US%QRZ_T_to_W_m2) + + handles%id_heat_content_lrunoff_glc = register_diag_field('ocean_model', 'heat_content_lrunoff_glc', & + diag%axesT1, Time, 'Heat content (relative to 0C) of liquid glc runoff into ocean', & + 'W m-2', conversion=US%QRZ_T_to_W_m2) + handles%id_hfrunoffds = register_diag_field('ocean_model', 'hfrunoffds', & diag%axesT1, Time, 'Heat content (relative to 0C) of liquid+solid runoff into ocean', & 'W m-2', conversion=US%QRZ_T_to_W_m2, & @@ -1843,6 +1911,8 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, cmor_standard_name='heat_flux_into_sea_water_due_to_snow_thermodynamics', & cmor_long_name='Latent Heat to Melt Frozen Precipitation') + ! Todo :check if below diagnostic field should include glc contribution, + ! or whether there should be a separate diagnostic field. handles%id_lat_frunoff = register_diag_field('ocean_model', 'latent_frunoff', diag%axesT1, Time, & 'Latent heat flux into ocean due to melting of icebergs', 'W m-2', conversion=US%QRZ_T_to_W_m2, & cmor_field_name='hfibthermds', & @@ -1870,6 +1940,8 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, !=============================================================== ! area integrated surface heat fluxes + ! Todo :check if below diagnostic field should include glc contribution, + ! or whether there should be a separate diagnostic field. handles%id_total_heat_content_frunoff = register_scalar_field('ocean_model', & 'total_heat_content_frunoff', Time, diag, & long_name='Area integrated heat content (relative to 0C) of solid runoff', & @@ -1879,6 +1951,8 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, cmor_long_name= & 'Temperature Flux due to Solid Runoff Expressed as Heat Flux into Sea Water Area Integrated') + ! Todo :check if below diagnostic field should include glc contribution, + ! or whether there should be a separate diagnostic field. handles%id_total_heat_content_lrunoff = register_scalar_field('ocean_model', & 'total_heat_content_lrunoff', Time, diag, & long_name='Area integrated heat content (relative to 0C) of liquid runoff', & @@ -1996,6 +2070,8 @@ subroutine register_forcing_type_diags(Time, diag, US, use_temperature, handles, cmor_long_name= & 'Latent Heat to Melt Frozen Precipitation Area Integrated') + ! Todo :check if below diagnostic field should include glc contribution, + ! or whether there should be a separate diagnostic field. handles%id_total_lat_frunoff = register_scalar_field('ocean_model', & 'total_lat_frunoff', Time, diag, & long_name='Area integrated latent heat flux due to melting icebergs', & @@ -2268,6 +2344,8 @@ subroutine fluxes_accumulate(flux_tmp, fluxes, G, wt2, forces) fluxes%vprec(i,j) = wt1*fluxes%vprec(i,j) + wt2*flux_tmp%vprec(i,j) fluxes%lrunoff(i,j) = wt1*fluxes%lrunoff(i,j) + wt2*flux_tmp%lrunoff(i,j) fluxes%frunoff(i,j) = wt1*fluxes%frunoff(i,j) + wt2*flux_tmp%frunoff(i,j) + fluxes%lrunoff_glc(i,j) = wt1*fluxes%lrunoff_glc(i,j) + wt2*flux_tmp%lrunoff_glc(i,j) + fluxes%frunoff_glc(i,j) = wt1*fluxes%frunoff_glc(i,j) + wt2*flux_tmp%frunoff_glc(i,j) fluxes%seaice_melt(i,j) = wt1*fluxes%seaice_melt(i,j) + wt2*flux_tmp%seaice_melt(i,j) fluxes%sw(i,j) = wt1*fluxes%sw(i,j) + wt2*flux_tmp%sw(i,j) fluxes%sw_vis_dir(i,j) = wt1*fluxes%sw_vis_dir(i,j) + wt2*flux_tmp%sw_vis_dir(i,j) @@ -2321,6 +2399,16 @@ subroutine fluxes_accumulate(flux_tmp, fluxes, G, wt2, forces) fluxes%heat_content_frunoff(i,j) = wt1*fluxes%heat_content_frunoff(i,j) + wt2*flux_tmp%heat_content_frunoff(i,j) enddo ; enddo endif + if (associated(fluxes%heat_content_lrunoff_glc) .and. associated(flux_tmp%heat_content_lrunoff_glc)) then + do j=js,je ; do i=is,ie + fluxes%heat_content_lrunoff_glc(i,j) = wt1*fluxes%heat_content_lrunoff_glc(i,j) + wt2*flux_tmp%heat_content_lrunoff_glc(i,j) + enddo ; enddo + endif + if (associated(fluxes%heat_content_frunoff_glc) .and. associated(flux_tmp%heat_content_frunoff_glc)) then + do j=js,je ; do i=is,ie + fluxes%heat_content_frunoff_glc(i,j) = wt1*fluxes%heat_content_frunoff_glc(i,j) + wt2*flux_tmp%heat_content_frunoff_glc(i,j) + enddo ; enddo + endif if (associated(fluxes%ustar_shelf) .and. associated(flux_tmp%ustar_shelf)) then do i=isd,ied ; do j=jsd,jed @@ -2492,6 +2580,12 @@ subroutine get_net_mass_forcing(fluxes, G, US, net_mass_src) if (associated(fluxes%frunoff)) then ; do j=js,je ; do i=is,ie net_mass_src(i,j) = net_mass_src(i,j) + fluxes%frunoff(i,j) enddo ; enddo ; endif + if (associated(fluxes%lrunoff_glc)) then ; do j=js,je ; do i=is,ie + net_mass_src(i,j) = net_mass_src(i,j) + fluxes%lrunoff_glc(i,j) + enddo ; enddo ; endif + if (associated(fluxes%frunoff_glc)) then ; do j=js,je ; do i=is,ie + net_mass_src(i,j) = net_mass_src(i,j) + fluxes%frunoff_glc(i,j) + enddo ; enddo ; endif if (associated(fluxes%evap)) then ; do j=js,je ; do i=is,ie net_mass_src(i,j) = net_mass_src(i,j) + fluxes%evap(i,j) enddo ; enddo ; endif @@ -2652,6 +2746,8 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h if (associated(fluxes%evap)) res(i,j) = res(i,j) + fluxes%evap(i,j) if (associated(fluxes%lrunoff)) res(i,j) = res(i,j) + fluxes%lrunoff(i,j) if (associated(fluxes%frunoff)) res(i,j) = res(i,j) + fluxes%frunoff(i,j) + if (associated(fluxes%lrunoff_glc)) res(i,j) = res(i,j) + fluxes%lrunoff_glc(i,j) + if (associated(fluxes%frunoff_glc)) res(i,j) = res(i,j) + fluxes%frunoff_glc(i,j) if (associated(fluxes%vprec)) res(i,j) = res(i,j) + fluxes%vprec(i,j) if (associated(fluxes%seaice_melt)) res(i,j) = res(i,j) + fluxes%seaice_melt(i,j) enddo ; enddo @@ -2699,6 +2795,8 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h if (associated(fluxes%fprec)) res(i,j) = res(i,j) + fluxes%fprec(i,j) if (associated(fluxes%lrunoff)) res(i,j) = res(i,j) + fluxes%lrunoff(i,j) if (associated(fluxes%frunoff)) res(i,j) = res(i,j) + fluxes%frunoff(i,j) + if (associated(fluxes%lrunoff_glc)) res(i,j) = res(i,j) + fluxes%lrunoff_glc(i,j) + if (associated(fluxes%frunoff_glc)) res(i,j) = res(i,j) + fluxes%frunoff_glc(i,j) if (associated(fluxes%lprec)) then if (fluxes%lprec(i,j) > 0.0) res(i,j) = res(i,j) + fluxes%lprec(i,j) @@ -2802,6 +2900,22 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h endif endif + if (associated(fluxes%lrunoff_glc)) then + if (handles%id_lrunoff_glc > 0) call post_data(handles%id_lrunoff_glc, fluxes%lrunoff_glc, diag) + if (handles%id_total_lrunoff_glc > 0) then + total_transport = global_area_integral(fluxes%lrunoff_glc, G, scale=US%RZ_T_to_kg_m2s) + call post_data(handles%id_total_lrunoff_glc, total_transport, diag) + endif + endif + + if (associated(fluxes%frunoff_glc)) then + if (handles%id_frunoff_glc > 0) call post_data(handles%id_frunoff_glc, fluxes%frunoff_glc, diag) + if (handles%id_total_frunoff_glc > 0) then + total_transport = global_area_integral(fluxes%frunoff_glc, G, scale=US%RZ_T_to_kg_m2s) + call post_data(handles%id_total_frunoff_glc, total_transport, diag) + endif + endif + if (associated(fluxes%seaice_melt)) then if (handles%id_seaice_melt > 0) call post_data(handles%id_seaice_melt, fluxes%seaice_melt, diag) if (handles%id_total_seaice_melt > 0) then @@ -2826,6 +2940,12 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h call post_data(handles%id_total_heat_content_frunoff, total_transport, diag) endif + if ((handles%id_heat_content_lrunoff_glc > 0) .and. associated(fluxes%heat_content_lrunoff_glc)) & + call post_data(handles%id_heat_content_lrunoff_glc, fluxes%heat_content_lrunoff_glc, diag) + + if ((handles%id_heat_content_frunoff_glc > 0) .and. associated(fluxes%heat_content_frunoff_glc)) & + call post_data(handles%id_heat_content_frunoff_glc, fluxes%heat_content_frunoff_glc, diag) + if ((handles%id_heat_content_lprec > 0) .and. associated(fluxes%heat_content_lprec)) & call post_data(handles%id_heat_content_lprec, fluxes%heat_content_lprec, diag) if ((handles%id_total_heat_content_lprec > 0) .and. associated(fluxes%heat_content_lprec)) then @@ -2910,6 +3030,10 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h res(i,j) = res(i,j) + fluxes%heat_content_lrunoff(i,j) if (associated(fluxes%heat_content_frunoff)) & res(i,j) = res(i,j) + fluxes%heat_content_frunoff(i,j) + if (associated(fluxes%heat_content_lrunoff_glc)) & + res(i,j) = res(i,j) + fluxes%heat_content_lrunoff_glc(i,j) + if (associated(fluxes%heat_content_frunoff_glc)) & + res(i,j) = res(i,j) + fluxes%heat_content_frunoff_glc(i,j) if (associated(fluxes%heat_content_lprec)) & res(i,j) = res(i,j) + fluxes%heat_content_lprec(i,j) if (associated(fluxes%heat_content_fprec)) & @@ -2942,12 +3066,14 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h if (handles%id_heat_content_surfwater > 0 .or. handles%id_total_heat_content_surfwater > 0) then do j=js,je ; do i=is,ie res(i,j) = 0.0 - if (associated(fluxes%heat_content_lrunoff)) res(i,j) = res(i,j) + fluxes%heat_content_lrunoff(i,j) - if (associated(fluxes%heat_content_frunoff)) res(i,j) = res(i,j) + fluxes%heat_content_frunoff(i,j) - if (associated(fluxes%heat_content_lprec)) res(i,j) = res(i,j) + fluxes%heat_content_lprec(i,j) - if (associated(fluxes%heat_content_fprec)) res(i,j) = res(i,j) + fluxes%heat_content_fprec(i,j) - if (associated(fluxes%heat_content_vprec)) res(i,j) = res(i,j) + fluxes%heat_content_vprec(i,j) - if (associated(fluxes%heat_content_cond)) res(i,j) = res(i,j) + fluxes%heat_content_cond(i,j) + if (associated(fluxes%heat_content_lrunoff)) res(i,j) = res(i,j) + fluxes%heat_content_lrunoff(i,j) + if (associated(fluxes%heat_content_frunoff)) res(i,j) = res(i,j) + fluxes%heat_content_frunoff(i,j) + if (associated(fluxes%heat_content_lrunoff_glc)) res(i,j) = res(i,j) + fluxes%heat_content_lrunoff_glc(i,j) + if (associated(fluxes%heat_content_frunoff_glc)) res(i,j) = res(i,j) + fluxes%heat_content_frunoff_glc(i,j) + if (associated(fluxes%heat_content_lprec)) res(i,j) = res(i,j) + fluxes%heat_content_lprec(i,j) + if (associated(fluxes%heat_content_fprec)) res(i,j) = res(i,j) + fluxes%heat_content_fprec(i,j) + if (associated(fluxes%heat_content_vprec)) res(i,j) = res(i,j) + fluxes%heat_content_vprec(i,j) + if (associated(fluxes%heat_content_cond)) res(i,j) = res(i,j) + fluxes%heat_content_cond(i,j) if (mom_enthalpy) then if (associated(fluxes%heat_content_massout)) res(i,j) = res(i,j) + fluxes%heat_content_massout(i,j) else @@ -2967,6 +3093,8 @@ subroutine forcing_diagnostics(fluxes_in, sfc_state, G_in, US, time_end, diag, h res(i,j) = 0.0 if (associated(fluxes%heat_content_lrunoff)) res(i,j) = res(i,j) + fluxes%heat_content_lrunoff(i,j) if (associated(fluxes%heat_content_frunoff)) res(i,j) = res(i,j) + fluxes%heat_content_frunoff(i,j) + if (associated(fluxes%heat_content_lrunoff_glc)) res(i,j) = res(i,j) + fluxes%heat_content_lrunoff_glc(i,j) + if (associated(fluxes%heat_content_frunoff_glc)) res(i,j) = res(i,j) + fluxes%heat_content_frunoff_glc(i,j) enddo ; enddo call post_data(handles%id_hfrunoffds, res, diag) endif @@ -3255,6 +3383,8 @@ subroutine allocate_forcing_by_group(G, fluxes, water, heat, ustar, press, & call myAlloc(fluxes%vprec,isd,ied,jsd,jed, water) call myAlloc(fluxes%lrunoff,isd,ied,jsd,jed, water) call myAlloc(fluxes%frunoff,isd,ied,jsd,jed, water) + call myAlloc(fluxes%lrunoff_glc,isd,ied,jsd,jed, water) + call myAlloc(fluxes%frunoff_glc,isd,ied,jsd,jed, water) call myAlloc(fluxes%seaice_melt,isd,ied,jsd,jed, water) call myAlloc(fluxes%netMassOut,isd,ied,jsd,jed, water) call myAlloc(fluxes%netMassIn,isd,ied,jsd,jed, water) @@ -3277,6 +3407,8 @@ subroutine allocate_forcing_by_group(G, fluxes, water, heat, ustar, press, & call myAlloc(fluxes%heat_content_vprec,isd,ied,jsd,jed, .true.) call myAlloc(fluxes%heat_content_lrunoff,isd,ied,jsd,jed, .true.) call myAlloc(fluxes%heat_content_frunoff,isd,ied,jsd,jed, .true.) + call myAlloc(fluxes%heat_content_lrunoff_glc,isd,ied,jsd,jed, .true.) + call myAlloc(fluxes%heat_content_frunoff_glc,isd,ied,jsd,jed, .true.) call myAlloc(fluxes%heat_content_massout,isd,ied,jsd,jed, enthalpy_mom) call myAlloc(fluxes%heat_content_massin,isd,ied,jsd,jed, enthalpy_mom) endif ; endif @@ -3532,6 +3664,8 @@ subroutine deallocate_forcing_type(fluxes) if (associated(fluxes%heat_added)) deallocate(fluxes%heat_added) if (associated(fluxes%heat_content_lrunoff)) deallocate(fluxes%heat_content_lrunoff) if (associated(fluxes%heat_content_frunoff)) deallocate(fluxes%heat_content_frunoff) + if (associated(fluxes%heat_content_lrunoff_glc)) deallocate(fluxes%heat_content_lrunoff_glc) + if (associated(fluxes%heat_content_frunoff_glc)) deallocate(fluxes%heat_content_frunoff_glc) if (associated(fluxes%heat_content_lprec)) deallocate(fluxes%heat_content_lprec) if (associated(fluxes%heat_content_fprec)) deallocate(fluxes%heat_content_fprec) if (associated(fluxes%heat_content_cond)) deallocate(fluxes%heat_content_cond) @@ -3544,6 +3678,8 @@ subroutine deallocate_forcing_type(fluxes) if (associated(fluxes%vprec)) deallocate(fluxes%vprec) if (associated(fluxes%lrunoff)) deallocate(fluxes%lrunoff) if (associated(fluxes%frunoff)) deallocate(fluxes%frunoff) + if (associated(fluxes%lrunoff_glc)) deallocate(fluxes%lrunoff_glc) + if (associated(fluxes%frunoff_glc)) deallocate(fluxes%frunoff_glc) if (associated(fluxes%seaice_melt)) deallocate(fluxes%seaice_melt) if (associated(fluxes%netMassOut)) deallocate(fluxes%netMassOut) if (associated(fluxes%netMassIn)) deallocate(fluxes%netMassIn) @@ -3619,6 +3755,8 @@ subroutine rotate_forcing(fluxes_in, fluxes, turns) call rotate_array(fluxes_in%vprec, turns, fluxes%vprec) call rotate_array(fluxes_in%lrunoff, turns, fluxes%lrunoff) call rotate_array(fluxes_in%frunoff, turns, fluxes%frunoff) + call rotate_array(fluxes_in%lrunoff_glc, turns, fluxes%lrunoff_glc) + call rotate_array(fluxes_in%frunoff_glc, turns, fluxes%frunoff_glc) call rotate_array(fluxes_in%seaice_melt, turns, fluxes%seaice_melt) call rotate_array(fluxes_in%netMassOut, turns, fluxes%netMassOut) call rotate_array(fluxes_in%netMassIn, turns, fluxes%netMassIn) @@ -3645,7 +3783,9 @@ subroutine rotate_forcing(fluxes_in, fluxes, turns) call rotate_array(fluxes_in%heat_content_fprec, turns, fluxes%heat_content_fprec) call rotate_array(fluxes_in%heat_content_vprec, turns, fluxes%heat_content_vprec) call rotate_array(fluxes_in%heat_content_lrunoff, turns, fluxes%heat_content_lrunoff) + call rotate_array(fluxes_in%heat_content_lrunoff_glc, turns, fluxes%heat_content_lrunoff_glc) call rotate_array(fluxes_in%heat_content_frunoff, turns, fluxes%heat_content_frunoff) + call rotate_array(fluxes_in%heat_content_frunoff_glc, turns, fluxes%heat_content_frunoff_glc) if (associated (fluxes_in%heat_content_evap)) then call rotate_array(fluxes_in%heat_content_evap, turns, fluxes%heat_content_evap) else @@ -3883,6 +4023,8 @@ subroutine homogenize_forcing(fluxes, G, GV, US) call homogenize_field_t(fluxes%vprec, G, tmp_scale=US%RZ_T_to_kg_m2s) call homogenize_field_t(fluxes%lrunoff, G, tmp_scale=US%RZ_T_to_kg_m2s) call homogenize_field_t(fluxes%frunoff, G, tmp_scale=US%RZ_T_to_kg_m2s) + call homogenize_field_t(fluxes%lrunoff_glc, G, tmp_scale=US%RZ_T_to_kg_m2s) + call homogenize_field_t(fluxes%frunoff_glc, G, tmp_scale=US%RZ_T_to_kg_m2s) call homogenize_field_t(fluxes%seaice_melt, G, tmp_scale=US%RZ_T_to_kg_m2s) ! These two calls might not be needed. call homogenize_field_t(fluxes%netMassOut, G, tmp_scale=GV%H_to_mks) @@ -3912,6 +4054,8 @@ subroutine homogenize_forcing(fluxes, G, GV, US) call homogenize_field_t(fluxes%heat_content_vprec, G, tmp_scale=US%QRZ_T_to_W_m2) call homogenize_field_t(fluxes%heat_content_lrunoff, G, tmp_scale=US%QRZ_T_to_W_m2) call homogenize_field_t(fluxes%heat_content_frunoff, G, tmp_scale=US%QRZ_T_to_W_m2) + call homogenize_field_t(fluxes%heat_content_lrunoff_glc, G, tmp_scale=US%QRZ_T_to_W_m2) + call homogenize_field_t(fluxes%heat_content_frunoff_glc, G, tmp_scale=US%QRZ_T_to_W_m2) call homogenize_field_t(fluxes%heat_content_massout, G, tmp_scale=US%QRZ_T_to_W_m2) call homogenize_field_t(fluxes%heat_content_massin, G, tmp_scale=US%QRZ_T_to_W_m2) endif diff --git a/src/diagnostics/MOM_sum_output.F90 b/src/diagnostics/MOM_sum_output.F90 index fb95b79a91..fdcee8107d 100644 --- a/src/diagnostics/MOM_sum_output.F90 +++ b/src/diagnostics/MOM_sum_output.F90 @@ -966,8 +966,8 @@ subroutine accumulate_net_input(fluxes, sfc_state, tv, dt, G, US, CS) if (associated(fluxes%lprec) .and. associated(fluxes%fprec)) then do j=js,je ; do i=is,ie FW_in(i,j) = RZL2_to_kg * dt*G%areaT(i,j)*(fluxes%evap(i,j) + & - (((fluxes%lprec(i,j) + fluxes%vprec(i,j)) + fluxes%lrunoff(i,j)) + & - (fluxes%fprec(i,j) + fluxes%frunoff(i,j)))) + (((fluxes%lprec(i,j) + fluxes%vprec(i,j)) + fluxes%lrunoff(i,j) + fluxes%lrunoff_glc(i,j)) + & + (fluxes%fprec(i,j) + fluxes%frunoff(i,j) + fluxes%frunoff_glc(i,j)))) enddo ; enddo else call MOM_error(WARNING, & diff --git a/src/parameterizations/vertical/MOM_bulk_mixed_layer.F90 b/src/parameterizations/vertical/MOM_bulk_mixed_layer.F90 index c7e522eddc..2af07e0ecf 100644 --- a/src/parameterizations/vertical/MOM_bulk_mixed_layer.F90 +++ b/src/parameterizations/vertical/MOM_bulk_mixed_layer.F90 @@ -525,13 +525,15 @@ subroutine bulkmixedlayer(h_3d, u_3d, v_3d, tv, fluxes, dt, ea, eb, G, GV, US, C RmixConst = -0.5*CS%rivermix_depth * GV%g_Earth do i=is,ie TKE_river(i) = max(0.0, RmixConst * dSpV0_dS(i) * & - (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j)) * S(i,1)) + (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j) + & + fluxes%lrunoff_glc(i,j) + fluxes%frunoff_glc(i,j)) * S(i,1)) enddo else RmixConst = 0.5*CS%rivermix_depth * GV%g_Earth * Irho0**2 do i=is,ie TKE_river(i) = max(0.0, RmixConst*dR0_dS(i)* & - (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j)) * S(i,1)) + (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j) + & + fluxes%lrunoff_glc(i,j) + fluxes%frunoff_glc(i,j)) * S(i,1)) enddo endif else diff --git a/src/parameterizations/vertical/MOM_diabatic_aux.F90 b/src/parameterizations/vertical/MOM_diabatic_aux.F90 index 6fdfdd5936..5c0011dadc 100644 --- a/src/parameterizations/vertical/MOM_diabatic_aux.F90 +++ b/src/parameterizations/vertical/MOM_diabatic_aux.F90 @@ -1442,7 +1442,8 @@ subroutine applyBoundaryFluxesInOut(CS, G, GV, US, dt, fluxes, optics, nsw, h, t RivermixConst = -0.5*(CS%rivermix_depth*dt) * GV%Rho0 * ( US%L_to_Z**2*GV%g_Earth ) endif cTKE(i,j,k) = cTKE(i,j,k) + max(0.0, RivermixConst*dSV_dS(i,j,1) * & - (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j)) * tv%S(i,j,1)) + (fluxes%lrunoff(i,j) + fluxes%frunoff(i,j) + & + fluxes%lrunoff_glc(i,j) + fluxes%frunoff_glc(i,j)) * tv%S(i,j,1)) endif ! Update state