SUBROUTINE RADIATION_SCHEME & & (YRADIATION,KIDIA, KFDIA, KLON, KLEV, KAEROSOL, & & PSOLAR_IRRADIANCE, & & PMU0, PTEMPERATURE_SKIN, PALBEDO_DIF, PALBEDO_DIR, & & PSPECTRALEMISS, & & PCCN_LAND, PCCN_SEA, & & PGELAM, PGEMU, PLAND_SEA_MASK, & & PPRESSURE, PTEMPERATURE, & & PPRESSURE_H, PTEMPERATURE_H, & & PQ, PCO2, PCH4, PN2O, PNO2, PCFC11, PCFC12, PHCFC22, PCCL4, PO3, & & PCLOUD_FRAC, PQ_LIQUID, PQ_ICE, PQ_RAIN, PQ_SNOW, & & PAEROSOL_OLD, PAEROSOL, & & PFLUX_SW, PFLUX_LW, PFLUX_SW_CLEAR, PFLUX_LW_CLEAR, & & PFLUX_SW_DN, PFLUX_LW_DN, PFLUX_SW_DN_CLEAR, PFLUX_LW_DN_CLEAR, & & PFLUX_DIR, PFLUX_DIR_CLEAR, PFLUX_DIR_INTO_SUN, & & PFLUX_UV, PFLUX_PAR, PFLUX_PAR_CLEAR, & & PFLUX_SW_DN_TOA, PEMIS_OUT, PLWDERIVATIVE, & & PSWDIFFUSEBAND, PSWDIRECTBAND) ! RADIATION_SCHEME - Interface to modular radiation scheme ! (C) Copyright 2015- 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. ! PURPOSE ! ------- ! The modular radiation scheme is contained in a separate ! library. This routine puts the the IFS arrays into appropriate ! objects, computing the additional data that is required, and sends ! it to the radiation scheme. It returns net fluxes and surface ! flux components needed by the rest of the model. ! Lower case is used for variables and types taken from the ! radiation library ! INTERFACE ! --------- ! RADIATION_SCHEME is called from RADLSWR. The ! SETUP_RADIATION_SCHEME routine (in the RADIATION_SETUP module) ! populates the YRADIATION object, and should have been run first. ! AUTHOR ! ------ ! Robin Hogan, ECMWF ! Original: 2015-09-16 ! MODIFICATIONS ! ------------- ! 2017-03-03 R. Hogan Read configuration data from YRADIATION object ! 2017-05-11 R. Hogan Pass KIDIA,KFDIA to get_layer_mass ! 2018-01-11 R. Hogan Capability to scale solar spectrum in each band ! 2017-11-11 M. Ahlgrimm add variable FSD for cloud heterogeneity ! 2017-11-29 R. Hogan Check fluxes in physical bounds ! 2019-01-22 R. Hogan Use fluxes in albedo bands from ecRad ! 2019-01-23 R. Hogan Spectral longwave emissivity in NLWEMISS bands ! 2019-02-04 R. Hogan Pass out surface longwave downwelling in each emissivity interval ! 2019-02-07 R. Hogan SPARTACUS cloud size from PARAM_CLOUD_EFFECTIVE_SEPARATION_ETA !----------------------------------------------------------------------- ! Modules from ifs or ifsaux libraries USE PARKIND1 , ONLY : JPIM, JPRB, JPRD USE YOMHOOK , ONLY : LHOOK, DR_HOOK, JPHOOK USE YOMCST , ONLY : RPI, RSIGMA ! Stefan-Boltzmann constant USE YOMLUN , ONLY : NULERR USE RADIATION_SETUP, ONLY : ITYPE_TROP_BG_AER, ITYPE_STRAT_BG_AER, TRADIATION ! Modules from ecRad radiation library USE RADIATION_CONFIG, ONLY : ISOLVERSPARTACUS USE RADIATION_SINGLE_LEVEL, ONLY : SINGLE_LEVEL_TYPE USE RADIATION_THERMODYNAMICS, ONLY : THERMODYNAMICS_TYPE USE RADIATION_GAS, ONLY : GAS_TYPE,& & IMASSMIXINGRATIO, IVOLUMEMIXINGRATIO,& & IH2O, ICO2, ICH4, IN2O, ICFC11, ICFC12, IHCFC22, ICCL4, IO3, IO2 USE RADIATION_CLOUD, ONLY : CLOUD_TYPE USE RADIATION_AEROSOL, ONLY : AEROSOL_TYPE USE RADIATION_FLUX, ONLY : FLUX_TYPE USE RADIATION_INTERFACE, ONLY : RADIATION, SET_GAS_UNITS USE RADIATION_SAVE, ONLY : SAVE_INPUTS, SAVE_FLUXES IMPLICIT NONE ! INPUT ARGUMENTS TYPE(TRADIATION), INTENT(IN) :: YRADIATION ! *** Array dimensions and ranges INTEGER(KIND=JPIM),INTENT(IN) :: KIDIA ! Start column to process INTEGER(KIND=JPIM),INTENT(IN) :: KFDIA ! End column to process INTEGER(KIND=JPIM),INTENT(IN) :: KLON ! Number of columns INTEGER(KIND=JPIM),INTENT(IN) :: KLEV ! Number of levels INTEGER(KIND=JPIM),INTENT(IN) :: KAEROSOL ! Number of aerosol types ! *** Single-level fields REAL(KIND=JPRB), INTENT(IN) :: PSOLAR_IRRADIANCE ! (W m-2) REAL(KIND=JPRB), INTENT(IN) :: PMU0(KLON) ! Cosine of solar zenith ang REAL(KIND=JPRB), INTENT(IN) :: PTEMPERATURE_SKIN(KLON) ! (K) ! Diffuse and direct components of surface shortwave albedo REAL(KIND=JPRB), INTENT(IN) :: PALBEDO_DIF(KLON,YRADIATION%YRERAD%NSW) REAL(KIND=JPRB), INTENT(IN) :: PALBEDO_DIR(KLON,YRADIATION%YRERAD%NSW) ! Longwave spectral emissivity REAL(KIND=JPRB), INTENT(IN) :: PSPECTRALEMISS(KLON,YRADIATION%YRERAD%NLWEMISS) ! Longitude (radians), sine of latitude REAL(KIND=JPRB), INTENT(IN) :: PGELAM(KLON) REAL(KIND=JPRB), INTENT(IN) :: PGEMU(KLON) ! Land-sea mask REAL(KIND=JPRB), INTENT(IN) :: PLAND_SEA_MASK(KLON) ! *** Variables on full levels REAL(KIND=JPRB), INTENT(IN) :: PPRESSURE(KLON,KLEV) ! (Pa) REAL(KIND=JPRB), INTENT(IN) :: PTEMPERATURE(KLON,KLEV) ! (K) ! *** Variables on half levels REAL(KIND=JPRB), INTENT(IN) :: PPRESSURE_H(KLON,KLEV+1) ! (Pa) REAL(KIND=JPRB), INTENT(IN) :: PTEMPERATURE_H(KLON,KLEV+1) ! (K) ! *** Gas mass mixing ratios on full levels REAL(KIND=JPRB), INTENT(IN) :: PQ(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PCO2(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PCH4(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PN2O(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PNO2(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PCFC11(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PCFC12(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PHCFC22(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PCCL4(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PO3(KLON,KLEV) ! *** Cloud fraction and hydrometeor mass mixing ratios REAL(KIND=JPRB), INTENT(IN) :: PCLOUD_FRAC(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PQ_LIQUID(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PQ_ICE(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PQ_RAIN(KLON,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PQ_SNOW(KLON,KLEV) ! *** Aerosol mass mixing ratios REAL(KIND=JPRB), INTENT(IN) :: PAEROSOL_OLD(KLON,6,KLEV) REAL(KIND=JPRB), INTENT(IN) :: PAEROSOL(KLON,KLEV,KAEROSOL) REAL(KIND=JPRB), INTENT(IN) :: PCCN_LAND(KLON) REAL(KIND=JPRB), INTENT(IN) :: PCCN_SEA(KLON) ! OUTPUT ARGUMENTS ! *** Net fluxes on half-levels (W m-2) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_SW(KLON,KLEV+1) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_LW(KLON,KLEV+1) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_SW_CLEAR(KLON,KLEV+1) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_LW_CLEAR(KLON,KLEV+1) ! *** Surface flux components (W m-2) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_SW_DN(KLON) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_LW_DN(KLON) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_SW_DN_CLEAR(KLON) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_LW_DN_CLEAR(KLON) ! Direct component of surface flux into horizontal plane REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_DIR(KLON) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_DIR_CLEAR(KLON) ! As PFLUX_DIR but into a plane perpendicular to the sun REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_DIR_INTO_SUN(KLON) ! *** Ultraviolet and photosynthetically active radiation (W m-2) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_UV(KLON) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_PAR(KLON) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_PAR_CLEAR(KLON) ! *** Other single-level diagnostics ! Top-of-atmosphere incident solar flux (W m-2) REAL(KIND=JPRB), INTENT(OUT) :: PFLUX_SW_DN_TOA(KLON) ! Diagnosed longwave surface emissivity across the whole spectrum REAL(KIND=JPRB), INTENT(OUT) :: PEMIS_OUT(KLON) ! Partial derivative of total-sky longwave upward flux at each level ! with respect to upward flux at surface, used to correct heating ! rates at gridpoints/timesteps between calls to the full radiation ! scheme. Note that this version uses the convention of level index ! increasing downwards, unlike the local variable ZLwDerivative that ! is returned from the LW radiation scheme. REAL(KIND=JPRB), INTENT(OUT) :: PLWDERIVATIVE(KLON,KLEV+1) ! Surface diffuse and direct downwelling shortwave flux in each ! shortwave albedo band, used in RADINTG to update the surface fluxes ! accounting for high-resolution albedo information REAL(KIND=JPRB), INTENT(OUT) :: PSWDIFFUSEBAND(KLON,YRADIATION%YRERAD%NSW) REAL(KIND=JPRB), INTENT(OUT) :: PSWDIRECTBAND (KLON,YRADIATION%YRERAD%NSW) ! LOCAL VARIABLES TYPE(SINGLE_LEVEL_TYPE) :: SINGLE_LEVEL TYPE(THERMODYNAMICS_TYPE) :: THERMODYNAMICS TYPE(GAS_TYPE) :: GAS TYPE(CLOUD_TYPE) :: YLCLOUD TYPE(AEROSOL_TYPE) :: AEROSOL TYPE(FLUX_TYPE) :: FLUX ! Cloud effective radii in microns REAL(KIND=JPRB) :: ZRE_LIQUID_UM(KLON,KLEV) REAL(KIND=JPRB) :: ZRE_ICE_UM(KLON,KLEV) ! Cloud overlap decorrelation length for cloud boundaries in km REAL(KIND=JPRB) :: ZDECORR_LEN_KM(KLON) ! Ratio of cloud overlap decorrelation length for cloud water ! inhomogeneities to that for cloud boundaries (typically 0.5) REAL(KIND=JPRB) :: ZDECORR_LEN_RATIO ! The surface net longwave flux if the surface was a black body, used ! to compute the effective broadband surface emissivity REAL(KIND=JPRB) :: ZBLACK_BODY_NET_LW(KIDIA:KFDIA) ! Layer mass in kg m-2 REAL(KIND=JPRB) :: ZLAYER_MASS(KIDIA:KFDIA,KLEV) ! Time integers ! INTEGER(KIND=JPIM) :: ITIM, IDAY ! Loop indices INTEGER(KIND=JPIM) :: JLON, JLEV, JBAND, JAER ! Have any fluxes been returned that are out of a physically ! reasonable range? This integer stores the number of blocks of fluxes ! that have contained a bad value so far, for this task. NetCDF files ! will be written up to the value of NAERAD:NDUMPBADINPUTS. INTEGER(KIND=JPIM), SAVE :: N_BAD_FLUXES = 0 ! For debugging it can be useful to save input profiles and output ! fluxes without the condition that the fluxes are out of a reasonable ! range. NetCDF files will be written up to the value of ! NAERAD:NDUMPINPUTS. INTEGER(KIND=JPIM), SAVE :: N_OUTPUT_FLUXES = 0 ! NetCDF file name in case of bad fluxes CHARACTER(LEN=512) :: CL_FILE_NAME REAL(KIND=JPHOOK) :: ZHOOK_HANDLE ! Dummy from YOMCT3 ! INTEGER(KIND=JPIM) :: NSTEP = 0 ! Dummy from MPL_MYRANK_MOD INTEGER(KIND=JPIM) :: MPL_MYRANK MPL_MYRANK() = 1 ! Import time functions for iseed calculation #include "fcttim.func.h" #include "liquid_effective_radius.intfb.h" #include "ice_effective_radius.intfb.h" #include "cloud_overlap_decorr_len.intfb.h" !#include "satur.intfb.h" !#include "abor1.intfb.h" IF (LHOOK) CALL DR_HOOK('RADIATION_SCHEME',0,ZHOOK_HANDLE) ASSOCIATE(YRERAD =>YRADIATION%YRERAD, & & RAD_CONFIG=>YRADIATION%RAD_CONFIG, & & NWEIGHT_UV=>YRADIATION%NWEIGHT_UV, & & IBAND_UV =>YRADIATION%IBAND_UV(:), & & WEIGHT_UV =>YRADIATION%WEIGHT_UV(:), & & NWEIGHT_PAR=>YRADIATION%NWEIGHT_PAR, & & IBAND_PAR =>YRADIATION%IBAND_PAR(:), & & WEIGHT_PAR=>YRADIATION%WEIGHT_PAR(:), & & TROP_BG_AER_MASS_EXT=>YRADIATION%TROP_BG_AER_MASS_EXT, & & STRAT_BG_AER_MASS_EXT=>YRADIATION%STRAT_BG_AER_MASS_EXT) ! Allocate memory in radiation objects CALL SINGLE_LEVEL%ALLOCATE(KLON, YRERAD%NSW, YRERAD%NLWEMISS, & & USE_SW_ALBEDO_DIRECT=.TRUE.) CALL THERMODYNAMICS%ALLOCATE(KLON, KLEV, USE_H2O_SAT=.TRUE.) CALL GAS%ALLOCATE(KLON, KLEV) CALL YLCLOUD%ALLOCATE(KLON, KLEV) IF (YRERAD%NAERMACC == 1) THEN CALL AEROSOL%ALLOCATE(KLON, 1, KLEV, KAEROSOL) ! MACC aerosols ELSE CALL AEROSOL%ALLOCATE(KLON, 1, KLEV, 6) ! Tegen climatology ENDIF CALL FLUX%ALLOCATE(RAD_CONFIG, 1, KLON, KLEV) ! Set thermodynamic profiles: simply copy over the half-level ! pressure and temperature THERMODYNAMICS%PRESSURE_HL (KIDIA:KFDIA,:) = PPRESSURE_H (KIDIA:KFDIA,:) THERMODYNAMICS%TEMPERATURE_HL(KIDIA:KFDIA,:) = PTEMPERATURE_H(KIDIA:KFDIA,:) ! IFS currently sets the half-level temperature at the surface to be ! equal to the skin temperature. The radiation scheme takes as input ! only the half-level temperatures and assumes the Planck function to ! vary linearly in optical depth between half levels. In the lowest ! atmospheric layer, where the atmospheric temperature can be much ! cooler than the skin temperature, this can lead to significant ! differences between the effective temperature of this lowest layer ! and the true value in the model. ! We may approximate the temperature profile in the lowest model level ! as piecewise linear between the top of the layer T[k-1/2], the ! centre of the layer T[k] and the base of the layer Tskin. The mean ! temperature of the layer is then 0.25*T[k-1/2] + 0.5*T[k] + ! 0.25*Tskin, which can be achieved by setting the atmospheric ! temperature at the half-level corresponding to the surface as ! follows: THERMODYNAMICS%TEMPERATURE_HL(KIDIA:KFDIA,KLEV+1)& & = PTEMPERATURE(KIDIA:KFDIA,KLEV)& & + 0.5_JPRB * (PTEMPERATURE_H(KIDIA:KFDIA,KLEV+1)& & -PTEMPERATURE_H(KIDIA:KFDIA,KLEV)) ! Alternatively we respect the model's atmospheric temperature in the ! lowest model level by setting the temperature at the lowest ! half-level such that the mean temperature of the layer is correct: !thermodynamics%temperature_hl(KIDIA:KFDIA,KLEV+1) & ! & = 2.0_JPRB * PTEMPERATURE(KIDIA:KFDIA,KLEV) & ! & - PTEMPERATURE_H(KIDIA:KFDIA,KLEV) ! Compute saturation specific humidity, used to hydrate aerosols. The ! "2" for the last argument indicates that the routine is not being ! called from within the convection scheme. !CALL SATUR(KIDIA, KFDIA, KLON, 1, KLEV, .false., & ! & PPRESSURE, PTEMPERATURE, THERMODYNAMICS%H2O_SAT_LIQ, 2) ! Alternative approximate version using temperature and pressure from ! the thermodynamics structure CALL thermodynamics%calc_saturation_wrt_liquid(KIDIA, KFDIA) ! Set single-level fileds SINGLE_LEVEL%SOLAR_IRRADIANCE = PSOLAR_IRRADIANCE SINGLE_LEVEL%COS_SZA(KIDIA:KFDIA) = PMU0(KIDIA:KFDIA) SINGLE_LEVEL%SKIN_TEMPERATURE(KIDIA:KFDIA) = PTEMPERATURE_SKIN(KIDIA:KFDIA) SINGLE_LEVEL%SW_ALBEDO(KIDIA:KFDIA,:) = PALBEDO_DIF(KIDIA:KFDIA,:) SINGLE_LEVEL%SW_ALBEDO_DIRECT(KIDIA:KFDIA,:)=PALBEDO_DIR(KIDIA:KFDIA,:) ! Spectral longwave emissivity SINGLE_LEVEL%LW_EMISSIVITY(KIDIA:KFDIA,:) = PSPECTRALEMISS(KIDIA:KFDIA,:) ! Create the relevant seed from date and time get the starting day ! and number of minutes since start ! IDAY = NDD(NINDAT) ! ITIM = NINT(NSTEP * YDMODEL%YRML_GCONF%YRRIP%TSTEP / 60.0_JPRB) ! DO JLON = KIDIA, KFDIA ! ! This method gives a unique value for roughly every 1-km square ! ! on the globe and every minute. ASIN(PGEMU)*60 gives rough ! ! latitude in degrees, which we multiply by 100 to give a unique ! ! value for roughly every km. PGELAM*60*100 gives a unique number ! ! for roughly every km of longitude around the equator, which we ! ! multiply by 180*100 so there is no overlap with the latitude ! ! values. The result can be contained in a 32-byte integer (but ! ! since random numbers are generated with the help of integer ! ! overflow, it should not matter if the number did overflow). ! SINGLE_LEVEL%ISEED(JLON) = ITIM + IDAY & ! & + NINT(PGELAM(JLON)*108000000.0_JPRD & ! & + ASIN(PGEMU(JLON))*6000.0_JPRD) ! ENDDO ! Simple initialization of the seeds for the Monte Carlo scheme call single_level%init_seed_simple(kidia, kfdia) ! Set the solar spectrum scaling, if required IF (YRERAD%NSOLARSPECTRUM == 1) THEN ALLOCATE(SINGLE_LEVEL%SPECTRAL_SOLAR_SCALING(RAD_CONFIG%N_BANDS_SW)) ! Ratio of SORCE (Coddington et al. 2016) and Kurucz solar spectra SINGLE_LEVEL%SPECTRAL_SOLAR_SCALING & & = (/ 1.0, 1.0, 1.0, 1.0478, 1.0404, 1.0317, 1.0231, & & 1.0054, 0.98413, 0.99863, 0.99907, 0.90589, 0.92213, 1.0 /) ENDIF ! Set cloud fields YLCLOUD%Q_LIQ(KIDIA:KFDIA,:) = PQ_LIQUID(KIDIA:KFDIA,:) YLCLOUD%Q_ICE(KIDIA:KFDIA,:) = PQ_ICE(KIDIA:KFDIA,:) + PQ_SNOW(KIDIA:KFDIA,:) YLCLOUD%FRACTION(KIDIA:KFDIA,:) = PCLOUD_FRAC(KIDIA:KFDIA,:) ! Compute effective radii and convert to metres CALL LIQUID_EFFECTIVE_RADIUS(YRERAD, & & KIDIA, KFDIA, KLON, KLEV, & & PPRESSURE, PTEMPERATURE, PCLOUD_FRAC, PQ_LIQUID, PQ_RAIN, & & PLAND_SEA_MASK, PCCN_LAND, PCCN_SEA, & & ZRE_LIQUID_UM) !, PPERT=PPERT) YLCLOUD%RE_LIQ(KIDIA:KFDIA,:) = ZRE_LIQUID_UM(KIDIA:KFDIA,:) * 1.0E-6_JPRB CALL ICE_EFFECTIVE_RADIUS(YRERAD, KIDIA, KFDIA, KLON, KLEV, & & PPRESSURE, PTEMPERATURE, PCLOUD_FRAC, PQ_ICE, PQ_SNOW, PGEMU, & & ZRE_ICE_UM) !, PPERT=PPERT) YLCLOUD%RE_ICE(KIDIA:KFDIA,:) = ZRE_ICE_UM(KIDIA:KFDIA,:) * 1.0E-6_JPRB ! Get the cloud overlap decorrelation length (for cloud boundaries), ! in km, according to the parameterization specified by NDECOLAT, ! and insert into the "cloud" object. Also get the ratio of ! decorrelation lengths for cloud water content inhomogeneities and ! cloud boundaries, and set it in the "rad_config" object. CALL CLOUD_OVERLAP_DECORR_LEN(KIDIA,KFDIA,KLON, & & PGEMU,YRERAD%NDECOLAT, & & PDECORR_LEN_EDGES_KM=ZDECORR_LEN_KM, PDECORR_LEN_RATIO=ZDECORR_LEN_RATIO) ! Compute cloud overlap parameter from decorrelation length !RAD_CONFIG%CLOUD_INHOM_DECORR_SCALING = ZDECORR_LEN_RATIO DO JLON = KIDIA,KFDIA CALL YLCLOUD%SET_OVERLAP_PARAM(THERMODYNAMICS,& & ZDECORR_LEN_KM(JLON)*1000.0_JPRB,& & ISTARTCOL=JLON, IENDCOL=JLON) ENDDO ! Or we can call the routine on all columns at once !CALL YLCLOUD%SET_OVERLAP_PARAM(THERMODYNAMICS,& ! & ZDECORR_LEN_KM(KIDIA:KFDIA)*1000.0_JPRB,& ! & ISTARTCOL=KIDIA, IENDCOL=KFDIA) ! Cloud water content fractional standard deviation is configurable ! from namelist NAERAD but must be globally constant. Before it was ! hard coded at 1.0. CALL YLCLOUD%CREATE_FRACTIONAL_STD(KLON, KLEV, YRERAD%RCLOUD_FRAC_STD) IF ( RAD_CONFIG%I_SOLVER_LW == ISOLVERSPARTACUS & & .OR. RAD_CONFIG%I_SOLVER_SW == ISOLVERSPARTACUS) THEN ! We are using the SPARTACUS solver so need to specify cloud scale, ! and use Mark Fielding's parameterization based on ARM data CALL YLCLOUD%PARAM_CLOUD_EFFECTIVE_SEPARATION_ETA(KLON, KLEV, & & PPRESSURE_H, YRERAD%RCLOUD_SEPARATION_SCALE_SURF, & & YRERAD%RCLOUD_SEPARATION_SCALE_TOA, 3.5_JPRB, 0.75_JPRB, & & KIDIA, KFDIA) ENDIF ! Compute the dry mass of each layer neglecting humidity effects, in ! kg m-2, needed to scale some of the aerosol inputs CALL THERMODYNAMICS%GET_LAYER_MASS(KIDIA,KFDIA,ZLAYER_MASS) ! Copy over aerosol mass mixing ratio IF (YRERAD%NAERMACC == 1) THEN ! MACC aerosol from climatology or prognostic aerosol variables - ! this is already in mass mixing ratio units with the required array ! orientation so we can copy it over directly ! AB need to cap the minimum mass mixing ratio/AOD to avoid instability ! in case of negative values in input DO JAER = 1,KAEROSOL DO JLEV = 1,KLEV DO JLON = KIDIA,KFDIA AEROSOL%MIXING_RATIO(JLON,JLEV,JAER) = MAX(PAEROSOL(JLON,JLEV,JAER),0.0_JPRB) ENDDO ENDDO ENDDO IF (YRERAD%NAERMACC == 1) THEN ! Add the tropospheric and stratospheric backgrounds contained in the ! old Tegen arrays - this is very ugly! IF (TROP_BG_AER_MASS_EXT > 0.0_JPRB) THEN AEROSOL%MIXING_RATIO(KIDIA:KFDIA,:,ITYPE_TROP_BG_AER)& & = AEROSOL%MIXING_RATIO(KIDIA:KFDIA,:,ITYPE_TROP_BG_AER)& & + PAEROSOL_OLD(KIDIA:KFDIA,1,:)& & / (ZLAYER_MASS * TROP_BG_AER_MASS_EXT) ENDIF IF (STRAT_BG_AER_MASS_EXT > 0.0_JPRB) THEN AEROSOL%MIXING_RATIO(KIDIA:KFDIA,:,ITYPE_STRAT_BG_AER)& & = AEROSOL%MIXING_RATIO(KIDIA:KFDIA,:,ITYPE_STRAT_BG_AER)& & + PAEROSOL_OLD(KIDIA:KFDIA,6,:)& & / (ZLAYER_MASS * STRAT_BG_AER_MASS_EXT) ENDIF ENDIF ELSE ! Tegen aerosol climatology - the array PAEROSOL_OLD contains the ! 550-nm optical depth in each layer. The optics data file ! aerosol_ifs_rrtm_tegen.nc does not contain mass extinction ! coefficient, but a scaling factor that the 550-nm optical depth ! should be multiplied by to obtain the optical depth in each ! spectral band. Therefore, in order for the units to work out, we ! need to divide by the layer mass (in kg m-2) to obtain the 550-nm ! cross-section per unit mass of dry air (so in m2 kg-1). We also ! need to permute the array. DO JLEV = 1,KLEV DO JAER = 1,6 AEROSOL%MIXING_RATIO(KIDIA:KFDIA,JLEV,JAER)& & = PAEROSOL_OLD(KIDIA:KFDIA,JAER,JLEV)& & / ZLAYER_MASS(KIDIA:KFDIA,JLEV) ENDDO ENDDO ENDIF ! Insert gas mixing ratios CALL GAS%PUT(IH2O, IMASSMIXINGRATIO, PQ) CALL GAS%PUT(ICO2, IMASSMIXINGRATIO, PCO2) CALL GAS%PUT(ICH4, IMASSMIXINGRATIO, PCH4) CALL GAS%PUT(IN2O, IMASSMIXINGRATIO, PN2O) CALL GAS%PUT(ICFC11, IMASSMIXINGRATIO, PCFC11) CALL GAS%PUT(ICFC12, IMASSMIXINGRATIO, PCFC12) CALL GAS%PUT(IHCFC22, IMASSMIXINGRATIO, PHCFC22) CALL GAS%PUT(ICCL4, IMASSMIXINGRATIO, PCCL4) CALL GAS%PUT(IO3, IMASSMIXINGRATIO, PO3) CALL GAS%PUT_WELL_MIXED(IO2, IVOLUMEMIXINGRATIO, 0.20944_JPRB) ! Ensure the units of the gas mixing ratios are what is required by ! the gas absorption model CALL SET_GAS_UNITS(RAD_CONFIG, GAS) !call save_inputs('inputs_ifs.nc', rad_config, single_level, thermodynamics, & ! & gas, ylcloud, aerosol, & ! & lat=spread(0.0_jprb,1,klon), & ! & lon=spread(0.0_jprb,1,klon), & ! & iverbose=2) ! Call radiation scheme CALL RADIATION(KLON, KLEV, KIDIA, KFDIA, RAD_CONFIG,& & SINGLE_LEVEL, THERMODYNAMICS, GAS, YLCLOUD, AEROSOL, FLUX) ! Check fluxes are within physical bounds IF (YRERAD%NDUMPBADINPUTS /= 0 & & .AND. (N_BAD_FLUXES == 0 .OR. N_BAD_FLUXES < YRERAD%NDUMPBADINPUTS)) THEN IF (FLUX%OUT_OF_PHYSICAL_BOUNDS(KIDIA,KFDIA)) THEN !$OMP CRITICAL N_BAD_FLUXES = N_BAD_FLUXES+1 WRITE(CL_FILE_NAME, '(A,I0,A,I0,A)') '/home/parr/ifs_dump/bad_inputs_', & & MPL_MYRANK(), '_', N_BAD_FLUXES, '.nc' WRITE(NULERR,*) ' Writing ', TRIM(CL_FILE_NAME) ! Implicit assumption that KFDIA==KLON CALL SAVE_INPUTS(TRIM(CL_FILE_NAME), RAD_CONFIG, SINGLE_LEVEL, & & THERMODYNAMICS, GAS, YLCLOUD, AEROSOL, & & LAT=ASIN(PGEMU)*180.0/RPI, LON=PGELAM*180.0/RPI, IVERBOSE=3) WRITE(CL_FILE_NAME, '(A,I0,A,I0,A)') '/home/parr/ifs_dump/bad_outputs_', & & MPL_MYRANK(), '_', N_BAD_FLUXES, '.nc' WRITE(NULERR,*) ' Writing ', TRIM(CL_FILE_NAME) CALL SAVE_FLUXES(TRIM(CL_FILE_NAME), RAD_CONFIG, THERMODYNAMICS, FLUX, IVERBOSE=3) IF (YRERAD%NDUMPBADINPUTS < 0) THEN ! Abort on the first set of bad fluxes CALL ABOR1("RADIATION_SCHEME: ABORT DUE TO FLUXES OUT OF PHYSICAL BOUNDS") ENDIF !$OMP END CRITICAL ENDIF ENDIF ! For debugging, do we store a certain number of inputs and outputs ! regardless of whether bad fluxes have been detected? IF (N_OUTPUT_FLUXES < YRERAD%NDUMPINPUTS) THEN !$OMP CRITICAL N_OUTPUT_FLUXES = N_OUTPUT_FLUXES+1 WRITE(CL_FILE_NAME, '(A,I0,A,I0,A)') '/home/parr/ifs_dump/inputs_', & & MPL_MYRANK(), '_', N_OUTPUT_FLUXES, '.nc' WRITE(NULERR,*) ' Writing ', TRIM(CL_FILE_NAME) ! Implicit assumption that KFDIA==KLON CALL SAVE_INPUTS(TRIM(CL_FILE_NAME), RAD_CONFIG, SINGLE_LEVEL, & & THERMODYNAMICS, GAS, YLCLOUD, AEROSOL, & & LAT=ASIN(PGEMU)*180.0/RPI, LON=PGELAM*180.0/RPI, IVERBOSE=3) WRITE(CL_FILE_NAME, '(A,I0,A,I0,A)') '/home/parr/ifs_dump/outputs_', & & MPL_MYRANK(), '_', N_OUTPUT_FLUXES, '.nc' WRITE(NULERR,*) ' Writing ', TRIM(CL_FILE_NAME) CALL SAVE_FLUXES(TRIM(CL_FILE_NAME), RAD_CONFIG, THERMODYNAMICS, FLUX, IVERBOSE=3) !$OMP END CRITICAL ENDIF ! Compute required output fluxes ! First the net fluxes PFLUX_SW(KIDIA:KFDIA,:) = FLUX%SW_DN(KIDIA:KFDIA,:) - FLUX%SW_UP(KIDIA:KFDIA,:) PFLUX_LW(KIDIA:KFDIA,:) = FLUX%LW_DN(KIDIA:KFDIA,:) - FLUX%LW_UP(KIDIA:KFDIA,:) PFLUX_SW_CLEAR(KIDIA:KFDIA,:)& & = FLUX%SW_DN_CLEAR(KIDIA:KFDIA,:) - FLUX%SW_UP_CLEAR(KIDIA:KFDIA,:) PFLUX_LW_CLEAR(KIDIA:KFDIA,:)& & = FLUX%LW_DN_CLEAR(KIDIA:KFDIA,:) - FLUX%LW_UP_CLEAR(KIDIA:KFDIA,:) ! Now the surface fluxes PFLUX_SW_DN (KIDIA:KFDIA) = FLUX%SW_DN (KIDIA:KFDIA,KLEV+1) PFLUX_LW_DN (KIDIA:KFDIA) = FLUX%LW_DN (KIDIA:KFDIA,KLEV+1) PFLUX_SW_DN_CLEAR(KIDIA:KFDIA) = FLUX%SW_DN_CLEAR (KIDIA:KFDIA,KLEV+1) PFLUX_LW_DN_CLEAR(KIDIA:KFDIA) = FLUX%LW_DN_CLEAR (KIDIA:KFDIA,KLEV+1) PFLUX_DIR (KIDIA:KFDIA) = FLUX%SW_DN_DIRECT (KIDIA:KFDIA,KLEV+1) PFLUX_DIR_CLEAR (KIDIA:KFDIA) = FLUX%SW_DN_DIRECT_CLEAR(KIDIA:KFDIA,KLEV+1) PFLUX_DIR_INTO_SUN(KIDIA:KFDIA) = 0.0_JPRB WHERE (PMU0(KIDIA:KFDIA) > EPSILON(1.0_JPRB)) PFLUX_DIR_INTO_SUN(KIDIA:KFDIA) = PFLUX_DIR(KIDIA:KFDIA) / PMU0(KIDIA:KFDIA) ENDWHERE ! Top-of-atmosphere downwelling flux PFLUX_SW_DN_TOA(KIDIA:KFDIA) = FLUX%SW_DN(KIDIA:KFDIA,1) ! Compute UV fluxes as weighted sum of appropriate shortwave bands PFLUX_UV (KIDIA:KFDIA) = 0.0_JPRB DO JBAND = 1,NWEIGHT_UV !DEC$ IVDEP PFLUX_UV(KIDIA:KFDIA) = PFLUX_UV(KIDIA:KFDIA) + WEIGHT_UV(JBAND)& & * FLUX%SW_DN_SURF_BAND(IBAND_UV(JBAND),KIDIA:KFDIA) ENDDO ! Compute photosynthetically active radiation similarly PFLUX_PAR (KIDIA:KFDIA) = 0.0_JPRB PFLUX_PAR_CLEAR(KIDIA:KFDIA) = 0.0_JPRB DO JBAND = 1,NWEIGHT_PAR !DEC$ IVDEP PFLUX_PAR(KIDIA:KFDIA) = PFLUX_PAR(KIDIA:KFDIA) + WEIGHT_PAR(JBAND)& & * FLUX%SW_DN_SURF_BAND(IBAND_PAR(JBAND),KIDIA:KFDIA) !DEC$ IVDEP PFLUX_PAR_CLEAR(KIDIA:KFDIA) = PFLUX_PAR_CLEAR(KIDIA:KFDIA)& & + WEIGHT_PAR(JBAND)& & * FLUX%SW_DN_SURF_CLEAR_BAND(IBAND_PAR(JBAND),KIDIA:KFDIA) ENDDO ! Compute effective broadband emissivity. This is only approximate - ! due to spectral variations in emissivity, it is not in general ! possible to provide a broadband emissivity that can reproduce the ! upwelling surface flux given the downwelling flux and the skin ! temperature. ZBLACK_BODY_NET_LW = PFLUX_LW_DN(KIDIA:KFDIA) & & - RSIGMA*PTEMPERATURE_SKIN(KIDIA:KFDIA)**4 PEMIS_OUT(KIDIA:KFDIA) = PSPECTRALEMISS(KIDIA:KFDIA,1) ! Default value WHERE (ABS(ZBLACK_BODY_NET_LW) > 1.0E-5) ! This calculation can go outside the range of any individual ! spectral emissivity value, so needs to be capped PEMIS_OUT(KIDIA:KFDIA) = MAX(0.8_JPRB, MIN(0.99_JPRB, PFLUX_LW(KIDIA:KFDIA,KLEV+1) / ZBLACK_BODY_NET_LW)) ENDWHERE ! Copy longwave derivatives IF (YRERAD%LAPPROXLWUPDATE) THEN PLWDERIVATIVE(KIDIA:KFDIA,:) = FLUX%LW_DERIVATIVES(KIDIA:KFDIA,:) ENDIF ! Store the shortwave downwelling fluxes in each albedo band IF (YRERAD%LAPPROXSWUPDATE) THEN PSWDIFFUSEBAND(KIDIA:KFDIA,:) = TRANSPOSE(FLUX%SW_DN_DIFFUSE_SURF_CANOPY(:,KIDIA:KFDIA)) PSWDIRECTBAND (KIDIA:KFDIA,:) = TRANSPOSE(FLUX%SW_DN_DIRECT_SURF_CANOPY (:,KIDIA:KFDIA)) ENDIF CALL SINGLE_LEVEL%DEALLOCATE CALL THERMODYNAMICS%DEALLOCATE CALL GAS%DEALLOCATE CALL YLCLOUD%DEALLOCATE CALL AEROSOL%DEALLOCATE CALL FLUX%DEALLOCATE END ASSOCIATE IF (LHOOK) CALL DR_HOOK('RADIATION_SCHEME',1,ZHOOK_HANDLE) END SUBROUTINE RADIATION_SCHEME