! radiation_interface.F90 - Public interface to radiation scheme ! (C) Copyright 2014- ECMWF. ! This software is licensed under the terms of the Apache Licence Version 2.0 ! which can be obtained at http://www.apache.org/licenses/LICENSE-2.0. ! In applying this licence, ECMWF does not waive the privileges and immunities ! granted to it by virtue of its status as an intergovernmental organisation ! nor does it submit to any jurisdiction. ! Author: Robin Hogan ! Email: r.j.hogan@ecmwf.int ! Modifications ! 2017-04-11 R. Hogan Changes to enable generalized surface description ! 2017-09-08 R. Hogan Reverted some changes ! To use the radiation scheme, create a configuration_type object, ! call "setup_radiation" on it once to load the look-up-tables and ! data describing how gas and hydrometeor absorption/scattering are to ! be represented, and call "radiation" multiple times on different ! input profiles. module radiation_interface implicit none public :: setup_radiation, set_gas_units, radiation private :: radiation_reverse contains !--------------------------------------------------------------------- ! Load the look-up-tables and data describing how gas and ! hydrometeor absorption/scattering are to be represented subroutine setup_radiation(config) use parkind1, only : jprb use yomhook, only : lhook, dr_hook use radiation_config, only : config_type, ISolverMcICA, & & IGasModelMonochromatic, IGasModelIFSRRTMG, IGasModelECCKD use radiation_spectral_definition, only & & : SolarReferenceTemperature, TerrestrialReferenceTemperature ! Currently there are two gas absorption models: RRTMG (default) ! and monochromatic use radiation_monochromatic, only : & & setup_gas_optics_mono => setup_gas_optics, & & setup_cloud_optics_mono => setup_cloud_optics, & & setup_aerosol_optics_mono => setup_aerosol_optics use radiation_ifs_rrtm, only : setup_gas_optics_rrtmg => setup_gas_optics use radiation_ecckd_interface,only : setup_gas_optics_ecckd => setup_gas_optics use radiation_cloud_optics, only : setup_cloud_optics use radiation_general_cloud_optics, only : setup_general_cloud_optics use radiation_aerosol_optics, only : setup_aerosol_optics type(config_type), intent(inout) :: config real(jprb) :: hook_handle if (lhook) call dr_hook('radiation_interface:setup_radiation',0,hook_handle) ! Consolidate configuration data, including setting data file ! names call config%consolidate() ! Load the look-up tables from files in the specified directory if (config%i_gas_model == IGasModelMonochromatic) then call setup_gas_optics_mono(config, trim(config%directory_name)) else if (config%i_gas_model == IGasModelIFSRRTMG) then call setup_gas_optics_rrtmg(config, trim(config%directory_name)) else if (config%i_gas_model == IGasModelECCKD) then call setup_gas_optics_ecckd(config) end if ! Whether or not the "radiation" subroutine needs ssa_lw and g_lw ! arrays depends on whether longwave scattering by aerosols is to ! be included. If not, one of the array dimensions will be set to ! zero. if (config%do_lw_aerosol_scattering) then config%n_g_lw_if_scattering = config%n_g_lw else config%n_g_lw_if_scattering = 0 end if ! Whether or not the "radiation" subroutine needs ssa_lw_cloud and ! g_lw_cloud arrays depends on whether longwave scattering by ! hydrometeors is to be included. If not, one of the array ! dimensions will be set to zero. if (config%do_lw_cloud_scattering) then config%n_bands_lw_if_scattering = config%n_bands_lw else config%n_bands_lw_if_scattering = 0 end if ! If we have longwave scattering and McICA then even if there is ! no aerosol, it is convenient if single scattering albedo and ! g factor arrays are allocated before the call to ! solver_lw as they will be needed. if (config%do_lw_cloud_scattering & & .AND. config%i_solver_lw == ISolverMcICA) then config%n_g_lw_if_scattering = config%n_g_lw end if ! Consolidate the albedo/emissivity intervals with the shortwave ! and longwave spectral bands if (config%do_sw) then call config%consolidate_sw_albedo_intervals end if if (config%do_lw) then call config%consolidate_lw_emiss_intervals end if if (config%do_clouds) then if (config%i_gas_model == IGasModelMonochromatic) then ! call setup_cloud_optics_mono(config) elseif (config%use_general_cloud_optics) then call setup_general_cloud_optics(config) else call setup_cloud_optics(config) end if end if if (config%use_aerosols) then if (config%i_gas_model == IGasModelMonochromatic) then ! call setup_aerosol_optics_mono(config) else call setup_aerosol_optics(config) end if end if ! Load cloud water PDF look-up table for McICA if ( config%i_solver_sw == ISolverMcICA & & .or. config%i_solver_lw == ISolverMcICA) then call config%pdf_sampler%setup(config%cloud_pdf_file_name, & & iverbose=config%iverbosesetup) end if if (lhook) call dr_hook('radiation_interface:setup_radiation',1,hook_handle) end subroutine setup_radiation !--------------------------------------------------------------------- ! Scale the gas mixing ratios so that they have the units (and ! possibly scale factors) required by the specific gas absorption ! model. This subroutine simply passes the gas object on to the ! module of the currently active gas model. subroutine set_gas_units(config, gas) use radiation_config use radiation_gas, only : gas_type use radiation_monochromatic, only : set_gas_units_mono => set_gas_units use radiation_ifs_rrtm, only : set_gas_units_ifs => set_gas_units use radiation_ecckd_interface, only : set_gas_units_ecckd => set_gas_units type(config_type), intent(in) :: config type(gas_type), intent(inout) :: gas if (config%i_gas_model == IGasModelMonochromatic) then call set_gas_units_mono(gas) elseif (config%i_gas_model == IGasModelECCKD) then call set_gas_units_ecckd(gas) else call set_gas_units_ifs(gas) end if end subroutine set_gas_units !--------------------------------------------------------------------- ! Run the radiation scheme according to the configuration in the ! config object. There are ncol profiles of which only istartcol to ! iendcol are to be processed, and there are nlev model levels. The ! output fluxes are written to the flux object, and all other ! objects contain the input variables. The variables may be defined ! either in order of increasing or decreasing pressure, but if in ! order of decreasing pressure then radiation_reverse will be called ! to reverse the order for the computation and then reverse the ! order of the output fluxes to match the inputs. subroutine radiation(ncol, nlev, istartcol, iendcol, config, & & single_level, thermodynamics, gas, cloud, aerosol, flux) use parkind1, only : jprb use yomhook, only : lhook, dr_hook use radiation_io, only : nulout use radiation_config, only : config_type, & & IGasModelMonochromatic, IGasModelIFSRRTMG, & & ISolverMcICA, ISolverSpartacus, ISolverHomogeneous, & & ISolverTripleclouds use radiation_single_level, only : single_level_type use radiation_thermodynamics, only : thermodynamics_type use radiation_gas, only : gas_type use radiation_cloud, only : cloud_type use radiation_aerosol, only : aerosol_type use radiation_flux, only : flux_type use radiation_spartacus_sw, only : solver_spartacus_sw use radiation_spartacus_lw, only : solver_spartacus_lw use radiation_tripleclouds_sw,only : solver_tripleclouds_sw use radiation_tripleclouds_lw,only : solver_tripleclouds_lw use radiation_mcica_sw, only : solver_mcica_sw use radiation_mcica_lw, only : solver_mcica_lw use radiation_cloudless_sw, only : solver_cloudless_sw use radiation_cloudless_lw, only : solver_cloudless_lw use radiation_homogeneous_sw, only : solver_homogeneous_sw use radiation_homogeneous_lw, only : solver_homogeneous_lw use radiation_save, only : save_radiative_properties ! Treatment of gas and hydrometeor optics use radiation_monochromatic, only : & & gas_optics_mono => gas_optics, & & cloud_optics_mono => cloud_optics, & & add_aerosol_optics_mono => add_aerosol_optics use radiation_ifs_rrtm, only : gas_optics_rrtmg => gas_optics use radiation_ecckd_interface,only : gas_optics_ecckd => gas_optics use radiation_cloud_optics, only : cloud_optics use radiation_general_cloud_optics, only : general_cloud_optics use radiation_aerosol_optics, only : add_aerosol_optics ! Inputs integer, intent(in) :: ncol ! number of columns integer, intent(in) :: nlev ! number of model levels integer, intent(in) :: istartcol, iendcol ! range of columns to process type(config_type), intent(in) :: config type(single_level_type), intent(in) :: single_level type(thermodynamics_type),intent(in) :: thermodynamics type(gas_type), intent(in) :: gas type(cloud_type), intent(inout):: cloud type(aerosol_type), intent(in) :: aerosol ! Output type(flux_type), intent(inout):: flux ! Local variables ! Layer optical depth, single scattering albedo and asymmetry factor of ! gases and aerosols at each longwave g-point, where the latter ! two variables are only defined if aerosol longwave scattering is ! enabled (otherwise both are treated as zero). real(jprb), dimension(config%n_g_lw,nlev,istartcol:iendcol) :: od_lw real(jprb), dimension(config%n_g_lw_if_scattering,nlev,istartcol:iendcol) :: & & ssa_lw, g_lw ! Layer in-cloud optical depth, single scattering albedo and ! asymmetry factor of hydrometeors in each longwave band, where ! the latter two variables are only defined if hydrometeor ! longwave scattering is enabled (otherwise both are treated as ! zero). real(jprb), dimension(config%n_bands_lw,nlev,istartcol:iendcol) :: od_lw_cloud real(jprb), dimension(config%n_bands_lw_if_scattering,nlev,istartcol:iendcol) :: & & ssa_lw_cloud, g_lw_cloud ! Layer optical depth, single scattering albedo and asymmetry factor of ! gases and aerosols at each shortwave g-point real(jprb), dimension(config%n_g_sw,nlev,istartcol:iendcol) :: od_sw, ssa_sw, g_sw ! Layer in-cloud optical depth, single scattering albedo and ! asymmetry factor of hydrometeors in each shortwave band real(jprb), dimension(config%n_bands_sw,nlev,istartcol:iendcol) :: & & od_sw_cloud, ssa_sw_cloud, g_sw_cloud ! The Planck function (emitted flux from a black body) at half ! levels real(jprb), dimension(config%n_g_lw,nlev+1,istartcol:iendcol) :: planck_hl ! The longwave emission from and albedo of the surface in each ! longwave g-point; note that these are weighted averages of the ! values from individual tiles real(jprb), dimension(config%n_g_lw, istartcol:iendcol) :: lw_emission real(jprb), dimension(config%n_g_lw, istartcol:iendcol) :: lw_albedo ! Direct and diffuse shortwave surface albedo in each shortwave ! g-point; note that these are weighted averages of the values ! from individual tiles real(jprb), dimension(config%n_g_sw, istartcol:iendcol) :: sw_albedo_direct real(jprb), dimension(config%n_g_sw, istartcol:iendcol) :: sw_albedo_diffuse ! The incoming shortwave flux into a plane perpendicular to the ! incoming radiation at top-of-atmosphere in each of the shortwave ! g-points real(jprb), dimension(config%n_g_sw,istartcol:iendcol) :: incoming_sw character(len=100) :: rad_prop_file_name character(*), parameter :: rad_prop_base_file_name = "radiative_properties" real(jprb) :: hook_handle if (lhook) call dr_hook('radiation_interface:radiation',0,hook_handle) if (thermodynamics%pressure_hl(istartcol,2) & & < thermodynamics%pressure_hl(istartcol,1)) then ! Input arrays are arranged in order of decreasing pressure / ! increasing height: the following subroutine reverses them, ! call the radiation scheme and then reverses the returned ! fluxes call radiation_reverse(ncol, nlev, istartcol, iendcol, config, & & single_level, thermodynamics, gas, cloud, aerosol, flux) else ! Input arrays arranged in order of increasing pressure / ! decreasing height: progress normally ! Extract surface albedos at each gridpoint call single_level%get_albedos(istartcol, iendcol, config, & & sw_albedo_direct, sw_albedo_diffuse, & & lw_albedo) ! Compute gas absorption optical depth in shortwave and ! longwave, shortwave single scattering albedo (i.e. fraction of ! extinction due to Rayleigh scattering), Planck functions and ! incoming shortwave flux at each g-point, for the specified ! range of atmospheric columns if (config%i_gas_model == IGasModelMonochromatic) then call gas_optics_mono(ncol,nlev,istartcol,iendcol, config, & & single_level, thermodynamics, gas, lw_albedo, & & od_lw, od_sw, ssa_sw, & & planck_hl, lw_emission, incoming_sw) else if (config%i_gas_model == IGasModelIFSRRTMG) then call gas_optics_rrtmg(ncol,nlev,istartcol,iendcol, config, & & single_level, thermodynamics, gas, & & od_lw, od_sw, ssa_sw, lw_albedo=lw_albedo, & & planck_hl=planck_hl, lw_emission=lw_emission, & & incoming_sw=incoming_sw) else call gas_optics_ecckd(ncol,nlev,istartcol,iendcol, config, & & single_level, thermodynamics, gas, & & od_lw, od_sw, ssa_sw, lw_albedo=lw_albedo, & & planck_hl=planck_hl, lw_emission=lw_emission, & & incoming_sw=incoming_sw) end if if (config%do_clouds) then ! Crop the cloud fraction to remove clouds that have too small ! a fraction or water content; after this, we can safely ! assume that a cloud is present if cloud%fraction > 0.0. call cloud%crop_cloud_fraction(istartcol, iendcol, & & config%cloud_fraction_threshold, & & config%cloud_mixing_ratio_threshold) ! Compute hydrometeor absorption/scattering properties in each ! shortwave and longwave band if (config%i_gas_model == IGasModelMonochromatic) then call cloud_optics_mono(nlev, istartcol, iendcol, & & config, thermodynamics, cloud, & & od_lw_cloud, ssa_lw_cloud, g_lw_cloud, & & od_sw_cloud, ssa_sw_cloud, g_sw_cloud) elseif (config%use_general_cloud_optics) then call general_cloud_optics(nlev, istartcol, iendcol, & & config, thermodynamics, cloud, & & od_lw_cloud, ssa_lw_cloud, g_lw_cloud, & & od_sw_cloud, ssa_sw_cloud, g_sw_cloud) else call cloud_optics(nlev, istartcol, iendcol, & & config, thermodynamics, cloud, & & od_lw_cloud, ssa_lw_cloud, g_lw_cloud, & & od_sw_cloud, ssa_sw_cloud, g_sw_cloud) end if end if ! do_clouds if (config%use_aerosols) then if (config%i_gas_model == IGasModelMonochromatic) then ! call add_aerosol_optics_mono(nlev,istartcol,iendcol, & ! & config, thermodynamics, gas, aerosol, & ! & od_lw, ssa_lw, g_lw, od_sw, ssa_sw, g_sw) else call add_aerosol_optics(nlev,istartcol,iendcol, & & config, thermodynamics, gas, aerosol, & & od_lw, ssa_lw, g_lw, od_sw, ssa_sw, g_sw) end if else g_sw(:,:,istartcol:iendcol) = 0.0_jprb if (config%do_lw_aerosol_scattering) then ssa_lw(:,:,istartcol:iendcol) = 0.0_jprb g_lw(:,:,istartcol:iendcol) = 0.0_jprb end if end if ! For diagnostic purposes, save these intermediate variables to ! a NetCDF file if (config%do_save_radiative_properties) then if (istartcol == 1 .AND. iendcol == ncol) then rad_prop_file_name = rad_prop_base_file_name // ".nc" else write(rad_prop_file_name,'(a,a,i4.4,a,i4.4,a)') & & rad_prop_base_file_name, '_', istartcol, '-',iendcol,'.nc' end if call save_radiative_properties(trim(rad_prop_file_name), & & nlev, istartcol, iendcol, & & config, single_level, thermodynamics, cloud, & & planck_hl, lw_emission, lw_albedo, & & sw_albedo_direct, sw_albedo_diffuse, incoming_sw, & & od_lw, ssa_lw, g_lw, od_sw, ssa_sw, g_sw, & & od_lw_cloud, ssa_lw_cloud, g_lw_cloud, & & od_sw_cloud, ssa_sw_cloud, g_sw_cloud) end if if (config%do_lw) then if (config%iverbose >= 2) then write(nulout,'(a)') 'Computing longwave fluxes' end if if (config%i_solver_lw == ISolverMcICA) then ! Compute fluxes using the McICA longwave solver call solver_mcica_lw(nlev,istartcol,iendcol, & & config, single_level, cloud, & & od_lw, ssa_lw, g_lw, od_lw_cloud, ssa_lw_cloud, & & g_lw_cloud, planck_hl, lw_emission, lw_albedo, flux) else if (config%i_solver_lw == ISolverSPARTACUS) then ! Compute fluxes using the SPARTACUS longwave solver call solver_spartacus_lw(nlev,istartcol,iendcol, & & config, thermodynamics, cloud, & & od_lw, ssa_lw, g_lw, od_lw_cloud, ssa_lw_cloud, g_lw_cloud, & & planck_hl, lw_emission, lw_albedo, flux) else if (config%i_solver_lw == ISolverTripleclouds) then ! Compute fluxes using the Tripleclouds longwave solver call solver_tripleclouds_lw(nlev,istartcol,iendcol, & & config, cloud, & & od_lw, ssa_lw, g_lw, od_lw_cloud, ssa_lw_cloud, g_lw_cloud, & & planck_hl, lw_emission, lw_albedo, flux) elseif (config%i_solver_lw == ISolverHomogeneous) then ! Compute fluxes using the homogeneous solver call solver_homogeneous_lw(nlev,istartcol,iendcol, & & config, cloud, & & od_lw, ssa_lw, g_lw, od_lw_cloud, ssa_lw_cloud, & & g_lw_cloud, planck_hl, lw_emission, lw_albedo, flux) else ! Compute fluxes using the cloudless solver call solver_cloudless_lw(nlev,istartcol,iendcol, & & config, od_lw, ssa_lw, g_lw, & & planck_hl, lw_emission, lw_albedo, flux) end if end if if (config%do_sw) then if (config%iverbose >= 2) then write(nulout,'(a)') 'Computing shortwave fluxes' end if if (config%i_solver_sw == ISolverMcICA) then ! Compute fluxes using the McICA shortwave solver call solver_mcica_sw(nlev,istartcol,iendcol, & & config, single_level, cloud, & & od_sw, ssa_sw, g_sw, od_sw_cloud, ssa_sw_cloud, & & g_sw_cloud, sw_albedo_direct, sw_albedo_diffuse, & & incoming_sw, flux) else if (config%i_solver_sw == ISolverSPARTACUS) then ! Compute fluxes using the SPARTACUS shortwave solver call solver_spartacus_sw(nlev,istartcol,iendcol, & & config, single_level, thermodynamics, cloud, & & od_sw, ssa_sw, g_sw, od_sw_cloud, ssa_sw_cloud, & & g_sw_cloud, sw_albedo_direct, sw_albedo_diffuse, & & incoming_sw, flux) else if (config%i_solver_sw == ISolverTripleclouds) then ! Compute fluxes using the Tripleclouds shortwave solver call solver_tripleclouds_sw(nlev,istartcol,iendcol, & & config, single_level, cloud, & & od_sw, ssa_sw, g_sw, od_sw_cloud, ssa_sw_cloud, & & g_sw_cloud, sw_albedo_direct, sw_albedo_diffuse, & & incoming_sw, flux) elseif (config%i_solver_sw == ISolverHomogeneous) then ! Compute fluxes using the homogeneous solver call solver_homogeneous_sw(nlev,istartcol,iendcol, & & config, single_level, cloud, & & od_sw, ssa_sw, g_sw, od_sw_cloud, ssa_sw_cloud, & & g_sw_cloud, sw_albedo_direct, sw_albedo_diffuse, & & incoming_sw, flux) else ! Compute fluxes using the cloudless solver call solver_cloudless_sw(nlev,istartcol,iendcol, & & config, single_level, od_sw, ssa_sw, g_sw, & & sw_albedo_direct, sw_albedo_diffuse, & & incoming_sw, flux) end if end if ! Store surface downwelling fluxes in bands from fluxes in g ! points call flux%calc_surface_spectral(config, istartcol, iendcol) end if if (lhook) call dr_hook('radiation_interface:radiation',1,hook_handle) end subroutine radiation !--------------------------------------------------------------------- ! If the input arrays are arranged in order of decreasing pressure / ! increasing height then this subroutine reverses them, calls the ! radiation scheme and then reverses the returned fluxes. Since this ! subroutine calls, and is called by "radiation", it must be in this ! module to avoid circular dependencies. subroutine radiation_reverse(ncol, nlev, istartcol, iendcol, config, & & single_level, thermodynamics, gas, cloud, aerosol, flux) use parkind1, only : jprb use radiation_io, only : nulout use radiation_config, only : config_type use radiation_single_level, only : single_level_type use radiation_thermodynamics, only : thermodynamics_type use radiation_gas, only : gas_type use radiation_cloud, only : cloud_type use radiation_aerosol, only : aerosol_type use radiation_flux, only : flux_type ! Inputs integer, intent(in) :: ncol ! number of columns integer, intent(in) :: nlev ! number of model levels integer, intent(in) :: istartcol, iendcol ! range of columns to process type(config_type), intent(in) :: config type(single_level_type), intent(in) :: single_level type(thermodynamics_type),intent(in) :: thermodynamics type(gas_type), intent(in) :: gas type(cloud_type), intent(in) :: cloud type(aerosol_type), intent(in) :: aerosol ! Output type(flux_type), intent(inout):: flux ! Reversed data structures type(thermodynamics_type) :: thermodynamics_rev type(gas_type) :: gas_rev type(cloud_type) :: cloud_rev type(aerosol_type) :: aerosol_rev type(flux_type) :: flux_rev ! Start and end levels for aerosol data integer :: istartlev, iendlev if (config%iverbose >= 2) then write(nulout,'(a)') 'Reversing arrays to be in order of increasing pressure' end if ! Allocate reversed arrays call thermodynamics_rev%allocate(ncol, nlev) call cloud_rev%allocate(ncol, nlev) call flux_rev%allocate(config, istartcol, iendcol, nlev) if (allocated(aerosol%mixing_ratio)) then istartlev = nlev + 1 - aerosol%iendlev iendlev = nlev + 1 - aerosol%istartlev call aerosol_rev%allocate(ncol, istartlev, iendlev, & & config%n_aerosol_types) end if ! Fill reversed thermodynamic arrays thermodynamics_rev%pressure_hl(istartcol:iendcol,:) & & = thermodynamics%pressure_hl(istartcol:iendcol, nlev+1:1:-1) thermodynamics_rev%temperature_hl(istartcol:iendcol,:) & & = thermodynamics%temperature_hl(istartcol:iendcol, nlev+1:1:-1) ! Fill reversed gas arrays call gas%reverse(istartcol, iendcol, gas_rev) if (config%do_clouds) then ! Fill reversed cloud arrays cloud_rev%q_liq(istartcol:iendcol,:) & & = cloud%q_liq(istartcol:iendcol,nlev:1:-1) cloud_rev%re_liq(istartcol:iendcol,:) & & = cloud%re_liq(istartcol:iendcol,nlev:1:-1) cloud_rev%q_ice(istartcol:iendcol,:) & & = cloud%q_ice(istartcol:iendcol,nlev:1:-1) cloud_rev%re_ice(istartcol:iendcol,:) & & = cloud%re_ice(istartcol:iendcol,nlev:1:-1) cloud_rev%fraction(istartcol:iendcol,:) & & = cloud%fraction(istartcol:iendcol,nlev:1:-1) cloud_rev%overlap_param(istartcol:iendcol,:) & & = cloud%overlap_param(istartcol:iendcol,nlev-1:1:-1) if (allocated(cloud%fractional_std)) then cloud_rev%fractional_std(istartcol:iendcol,:) & & = cloud%fractional_std(istartcol:iendcol,nlev:1:-1) else cloud_rev%fractional_std(istartcol:iendcol,:) = 0.0_jprb end if if (allocated(cloud%inv_cloud_effective_size)) then cloud_rev%inv_cloud_effective_size(istartcol:iendcol,:) & & = cloud%inv_cloud_effective_size(istartcol:iendcol,nlev:1:-1) else cloud_rev%inv_cloud_effective_size(istartcol:iendcol,:) = 0.0_jprb end if end if if (allocated(aerosol%mixing_ratio)) then aerosol_rev%mixing_ratio(:,istartlev:iendlev,:) & & = aerosol%mixing_ratio(:,aerosol%iendlev:aerosol%istartlev:-1,:) end if ! Run radiation scheme on reversed profiles call radiation(ncol, nlev,istartcol,iendcol, & & config, single_level, thermodynamics_rev, gas_rev, & & cloud_rev, aerosol_rev, flux_rev) ! Reorder fluxes if (allocated(flux%lw_up)) then flux%lw_up(istartcol:iendcol,:) & & = flux_rev%lw_up(istartcol:iendcol,nlev+1:1:-1) flux%lw_dn(istartcol:iendcol,:) & & = flux_rev%lw_dn(istartcol:iendcol,nlev+1:1:-1) if (allocated(flux%lw_up_clear)) then flux%lw_up_clear(istartcol:iendcol,:) & & = flux_rev%lw_up_clear(istartcol:iendcol,nlev+1:1:-1) flux%lw_dn_clear(istartcol:iendcol,:) & & = flux_rev%lw_dn_clear(istartcol:iendcol,nlev+1:1:-1) end if end if if (allocated(flux%sw_up)) then flux%sw_up(istartcol:iendcol,:) & & = flux_rev%sw_up(istartcol:iendcol,nlev+1:1:-1) flux%sw_dn(istartcol:iendcol,:) & & = flux_rev%sw_dn(istartcol:iendcol,nlev+1:1:-1) if (allocated(flux%sw_dn_direct)) then flux%sw_dn_direct(istartcol:iendcol,:) & & = flux_rev%sw_dn_direct(istartcol:iendcol,nlev+1:1:-1) end if if (allocated(flux%sw_up_clear)) then flux%sw_up_clear(istartcol:iendcol,:) & & = flux_rev%sw_up_clear(istartcol:iendcol,nlev+1:1:-1) flux%sw_dn_clear(istartcol:iendcol,:) & & = flux_rev%sw_dn_clear(istartcol:iendcol,nlev+1:1:-1) if (allocated(flux%sw_dn_direct_clear)) then flux%sw_dn_direct_clear(istartcol:iendcol,:) & & = flux_rev%sw_dn_direct_clear(istartcol:iendcol,nlev+1:1:-1) end if end if end if ! Deallocate reversed arrays call thermodynamics_rev%deallocate call gas_rev%deallocate call cloud_rev%deallocate call flux_rev%deallocate if (allocated(aerosol%mixing_ratio)) then call aerosol_rev%deallocate end if end subroutine radiation_reverse end module radiation_interface