! ! $Id: radlwsw_m.F90 4489 2023-03-31 18:42:57Z idelkadi $ ! module radlwsw_m IMPLICIT NONE contains SUBROUTINE radlwsw( & dist, rmu0, fract, & !albedo SB >>> ! paprs, pplay,tsol,alb1, alb2, & paprs, pplay,tsol,SFRWL,alb_dir, alb_dif, & !albedo SB <<< t,q,wo,& cldfra, cldemi, cldtaupd,& ok_ade, ok_aie, ok_volcan, flag_volc_surfstrat, flag_aerosol,& flag_aerosol_strat, flag_aer_feedback, & tau_aero, piz_aero, cg_aero,& tau_aero_sw_rrtm, piz_aero_sw_rrtm, cg_aero_sw_rrtm,& ! rajoute par OB RRTM tau_aero_lw_rrtm, & ! rajoute par C.Kleinschmitt pour RRTM cldtaupi, & qsat, flwc, fiwc, & ref_liq, ref_ice, ref_liq_pi, ref_ice_pi, & heat,heat0,cool,cool0,albpla,& heat_volc, cool_volc,& topsw,toplw,solsw,solswfdiff,sollw,& sollwdown,& topsw0,toplw0,solsw0,sollw0,& lwdnc0, lwdn0, lwdn, lwupc0, lwup0, lwup,& swdnc0, swdn0, swdn, swupc0, swup0, swup,& topswad_aero, solswad_aero,& topswai_aero, solswai_aero, & topswad0_aero, solswad0_aero,& topsw_aero, topsw0_aero,& solsw_aero, solsw0_aero, & topswcf_aero, solswcf_aero,& !-C. Kleinschmitt for LW diagnostics toplwad_aero, sollwad_aero,& toplwai_aero, sollwai_aero, & toplwad0_aero, sollwad0_aero, & !-end ZLWFT0_i, ZFLDN0, ZFLUP0,& ZSWFT0_i, ZFSDN0, ZFSUP0) ! Modules necessaires USE DIMPHY USE assert_m, ONLY : assert USE infotrac_phy, ONLY : type_trac USE write_field_phy #ifdef REPROBUS USE CHEM_REP, ONLY : solaireTIME, ok_SUNTIME, ndimozon #endif #ifdef CPP_RRTM ! modules necessaires au rayonnement ! ----------------------------------------- USE YOERAD , ONLY : NLW, LRRTM ,LCCNL ,LCCNO ,& NRADIP , NRADLP , NICEOPT, NLIQOPT ,RCCNLND , RCCNSEA USE YOELW , ONLY : NSIL ,NTRA ,NUA ,TSTAND ,XP USE YOESW , ONLY : RYFWCA ,RYFWCB ,RYFWCC ,RYFWCD,& RYFWCE ,RYFWCF ,REBCUA ,REBCUB ,REBCUC,& REBCUD ,REBCUE ,REBCUF ,REBCUI ,REBCUJ,& REBCUG ,REBCUH ,RHSAVI ,RFULIO ,RFLAA0,& RFLAA1 ,RFLBB0 ,RFLBB1 ,RFLBB2 ,RFLBB3,& RFLCC0 ,RFLCC1 ,RFLCC2 ,RFLCC3 ,RFLDD0,& RFLDD1 ,RFLDD2 ,RFLDD3 ,RFUETA ,RASWCA,& RASWCB ,RASWCC ,RASWCD ,RASWCE ,RASWCF USE YOERDU , ONLY : NUAER ,NTRAER ,REPLOG ,REPSC ,REPSCW ,DIFF USE YOERRTWN , ONLY : DELWAVE ,TOTPLNK USE YOMPHY3 , ONLY : RII0 #endif USE aero_mod ! AI 02.2021 ! Besoin pour ECRAD de pctsrf, zmasq, longitude, altitude #ifdef CPP_ECRAD USE phys_local_var_mod, ONLY: rhcl, m_allaer USE geometry_mod, ONLY: latitude, longitude USE phys_state_var_mod, ONLY: pctsrf USE indice_sol_mod USE time_phylmdz_mod, only: current_time USE phys_cal_mod, only: day_cur #endif !====================================================================== ! Auteur(s): Z.X. Li (LMD/CNRS) date: 19960719 ! Objet: interface entre le modele et les rayonnements ! Arguments: ! INPUTS ! dist----- input-R- distance astronomique terre-soleil ! rmu0----- input-R- cosinus de l'angle zenithal ! fract---- input-R- duree d'ensoleillement normalisee ! co2_ppm-- input-R- concentration du gaz carbonique (en ppm) ! paprs---- input-R- pression a inter-couche (Pa) ! pplay---- input-R- pression au milieu de couche (Pa) ! tsol----- input-R- temperature du sol (en K) ! alb1----- input-R- albedo du sol(entre 0 et 1) dans l'interval visible ! alb2----- input-R- albedo du sol(entre 0 et 1) dans l'interval proche infra-rouge ! t-------- input-R- temperature (K) ! q-------- input-R- vapeur d'eau (en kg/kg) ! cldfra--- input-R- fraction nuageuse (entre 0 et 1) ! cldtaupd- input-R- epaisseur optique des nuages dans le visible (present-day value) ! cldemi--- input-R- emissivite des nuages dans l'IR (entre 0 et 1) ! ok_ade--- input-L- apply the Aerosol Direct Effect or not? ! ok_aie--- input-L- apply the Aerosol Indirect Effect or not? ! ok_volcan input-L- activate volcanic diags (SW heat & LW cool rate, SW & LW flux) ! flag_volc_surfstrat input-I- activate volcanic surf cooling or strato heating (or nothing) ! flag_aerosol input-I- aerosol flag from 0 to 6 ! flag_aerosol_strat input-I- use stratospheric aerosols flag (0, 1, 2) ! flag_aer_feedback input-I- activate aerosol radiative feedback (T, F) ! tau_ae, piz_ae, cg_ae input-R- aerosol optical properties (calculated in aeropt.F) ! cldtaupi input-R- epaisseur optique des nuages dans le visible ! calculated for pre-industrial (pi) aerosol concentrations, i.e. with smaller ! droplet concentration, thus larger droplets, thus generally cdltaupi cldtaupd ! it is needed for the diagnostics of the aerosol indirect radiative forcing ! ! OUTPUTS ! heat-----output-R- echauffement atmospherique (visible) (K/jour) ! cool-----output-R- refroidissement dans l'IR (K/jour) ! albpla---output-R- albedo planetaire (entre 0 et 1) ! topsw----output-R- flux solaire net au sommet de l'atm. ! toplw----output-R- ray. IR montant au sommet de l'atmosphere ! solsw----output-R- flux solaire net a la surface ! solswfdiff----output-R- fraction de rayonnement diffus pour le flux solaire descendant a la surface ! sollw----output-R- ray. IR montant a la surface ! solswad---output-R- ray. solaire net absorbe a la surface (aerosol dir) ! topswad---output-R- ray. solaire absorbe au sommet de l'atm. (aerosol dir) ! solswai---output-R- ray. solaire net absorbe a la surface (aerosol ind) ! topswai---output-R- ray. solaire absorbe au sommet de l'atm. (aerosol ind) ! ! heat_volc-----output-R- echauffement atmospherique du au forcage volcanique (visible) (K/s) ! cool_volc-----output-R- refroidissement dans l'IR du au forcage volcanique (K/s) ! ! ATTENTION: swai and swad have to be interpreted in the following manner: ! --------- ! ok_ade=F & ok_aie=F -both are zero ! ok_ade=T & ok_aie=F -aerosol direct forcing is F_{AD} = topsw-topswad ! indirect is zero ! ok_ade=F & ok_aie=T -aerosol indirect forcing is F_{AI} = topsw-topswai ! direct is zero ! ok_ade=T & ok_aie=T -aerosol indirect forcing is F_{AI} = topsw-topswai ! aerosol direct forcing is F_{AD} = topswai-topswad ! ! --------- RRTM: output RECMWFL ! ZEMTD (KPROMA,KLEV+1) ; TOTAL DOWNWARD LONGWAVE EMISSIVITY ! ZEMTU (KPROMA,KLEV+1) ; TOTAL UPWARD LONGWAVE EMISSIVITY ! ZTRSO (KPROMA,KLEV+1) ; TOTAL SHORTWAVE TRANSMISSIVITY ! ZTH (KPROMA,KLEV+1) ; HALF LEVEL TEMPERATURE ! ZCTRSO(KPROMA,2) ; CLEAR-SKY SHORTWAVE TRANSMISSIVITY ! ZCEMTR(KPROMA,2) ; CLEAR-SKY NET LONGWAVE EMISSIVITY ! ZTRSOD(KPROMA) ; TOTAL-SKY SURFACE SW TRANSMISSITY ! ZLWFC (KPROMA,2) ; CLEAR-SKY LONGWAVE FLUXES ! ZLWFT (KPROMA,KLEV+1) ; TOTAL-SKY LONGWAVE FLUXES ! ZLWFT0(KPROMA,KLEV+1) ; CLEAR-SKY LONGWAVE FLUXES ! added by MPL 090109 ! ZSWFC (KPROMA,2) ; CLEAR-SKY SHORTWAVE FLUXES ! ZSWFT (KPROMA,KLEV+1) ; TOTAL-SKY SHORTWAVE FLUXES ! ZSWFT0(KPROMA,KLEV+1) ; CLEAR-SKY SHORTWAVE FLUXES ! added by MPL 090109 ! ZFLUX (KLON,2,KLEV+1) ; TOTAL LW FLUXES 1=up, 2=DWN ! added by MPL 080411 ! ZFLUC (KLON,2,KLEV+1) ; CLEAR SKY LW FLUXES ! added by MPL 080411 ! ZFSDWN(klon,KLEV+1) ; TOTAL SW DWN FLUXES ! added by MPL 080411 ! ZFCDWN(klon,KLEV+1) ; CLEAR SKY SW DWN FLUXES ! added by MPL 080411 ! ZFCCDWN(klon,KLEV+1) ; CLEAR SKY CLEAN (NO AEROSOL) SW DWN FLUXES ! added by OB 211117 ! ZFSUP (klon,KLEV+1) ; TOTAL SW UP FLUXES ! added by MPL 080411 ! ZFCUP (klon,KLEV+1) ; CLEAR SKY SW UP FLUXES ! added by MPL 080411 ! ZFCCUP (klon,KLEV+1) ; CLEAR SKY CLEAN (NO AEROSOL) SW UP FLUXES ! added by OB 211117 ! ZFLCCDWN(klon,KLEV+1) ; CLEAR SKY CLEAN (NO AEROSOL) LW DWN FLUXES ! added by OB 211117 ! ZFLCCUP (klon,KLEV+1) ; CLEAR SKY CLEAN (NO AEROSOL) LW UP FLUXES ! added by OB 211117 !====================================================================== ! ==================================================================== ! Adapte au modele de chimie INCA par Celine Deandreis & Anne Cozic -- 2009 ! 1 = ZERO ! 2 = AER total ! 3 = NAT ! 4 = BC ! 5 = SO4 ! 6 = POM ! 7 = DUST ! 8 = SS ! 9 = NO3 ! ! ==================================================================== ! ============== ! DECLARATIONS ! ============== include "YOETHF.h" include "YOMCST.h" include "clesphys.h" ! Input arguments REAL, INTENT(in) :: dist REAL, INTENT(in) :: rmu0(KLON), fract(KLON) REAL, INTENT(in) :: paprs(KLON,KLEV+1), pplay(KLON,KLEV) !albedo SB >>> ! REAL, INTENT(in) :: alb1(KLON), alb2(KLON), tsol(KLON) REAL, INTENT(in) :: tsol(KLON) REAL, INTENT(in) :: alb_dir(KLON,NSW),alb_dif(KLON,NSW) REAL, INTENT(in) :: SFRWL(6) !albedo SB <<< REAL, INTENT(in) :: t(KLON,KLEV), q(KLON,KLEV) REAL, INTENT(in):: wo(:, :, :) ! dimension(KLON,KLEV, 1 or 2) ! column-density of ozone in a layer, in kilo-Dobsons ! "wo(:, :, 1)" is for the average day-night field, ! "wo(:, :, 2)" is for daylight time. LOGICAL, INTENT(in) :: ok_ade, ok_aie ! switches whether to use aerosol direct (indirect) effects or not LOGICAL, INTENT(in) :: ok_volcan ! produce volcanic diags (SW/LW heat flux and rate) INTEGER, INTENT(in) :: flag_volc_surfstrat ! allow to impose volcanic cooling rate at surf or heating in strato LOGICAL :: lldebug=.false. INTEGER, INTENT(in) :: flag_aerosol ! takes value 0 (no aerosol) or 1 to 6 (aerosols) INTEGER, INTENT(in) :: flag_aerosol_strat ! use stratospheric aerosols LOGICAL, INTENT(in) :: flag_aer_feedback ! activate aerosol radiative feedback REAL, INTENT(in) :: cldfra(KLON,KLEV), cldemi(KLON,KLEV), cldtaupd(KLON,KLEV) REAL, INTENT(in) :: tau_aero(KLON,KLEV,naero_grp,2) ! aerosol optical properties (see aeropt.F) REAL, INTENT(in) :: piz_aero(KLON,KLEV,naero_grp,2) ! aerosol optical properties (see aeropt.F) REAL, INTENT(in) :: cg_aero(KLON,KLEV,naero_grp,2) ! aerosol optical properties (see aeropt.F) !--OB REAL, INTENT(in) :: tau_aero_sw_rrtm(KLON,KLEV,2,NSW) ! aerosol optical properties RRTM REAL, INTENT(in) :: piz_aero_sw_rrtm(KLON,KLEV,2,NSW) ! aerosol optical properties RRTM REAL, INTENT(in) :: cg_aero_sw_rrtm(KLON,KLEV,2,NSW) ! aerosol optical properties RRTM ! AI !--OB fin !--C. Kleinschmitt #ifdef CPP_RRTM REAL, INTENT(in) :: tau_aero_lw_rrtm(KLON,KLEV,2,NLW) ! LW aerosol optical properties RRTM #else REAL, INTENT(in) :: tau_aero_lw_rrtm(KLON,KLEV,2,nbands_lw_rrtm) #endif !--C. Kleinschmitt end REAL, INTENT(in) :: cldtaupi(KLON,KLEV) ! cloud optical thickness for pre-industrial aerosol concentrations REAL, INTENT(in) :: qsat(klon,klev) ! Variable pour iflag_rrtm=1 REAL, INTENT(in) :: flwc(klon,klev) ! Variable pour iflag_rrtm=1 REAL, INTENT(in) :: fiwc(klon,klev) ! Variable pour iflag_rrtm=1 REAL, INTENT(in) :: ref_liq(klon,klev) ! cloud droplet radius present-day from newmicro REAL, INTENT(in) :: ref_ice(klon,klev) ! ice crystal radius present-day from newmicro REAL, INTENT(in) :: ref_liq_pi(klon,klev) ! cloud droplet radius pre-industrial from newmicro REAL, INTENT(in) :: ref_ice_pi(klon,klev) ! ice crystal radius pre-industrial from newmicro ! Output arguments REAL, INTENT(out) :: heat(KLON,KLEV), cool(KLON,KLEV) REAL, INTENT(out) :: heat0(KLON,KLEV), cool0(KLON,KLEV) REAL, INTENT(out) :: heat_volc(KLON,KLEV), cool_volc(KLON,KLEV) !NL REAL, INTENT(out) :: topsw(KLON), toplw(KLON) REAL, INTENT(out) :: solsw(KLON), sollw(KLON), albpla(KLON), solswfdiff(KLON) REAL, INTENT(out) :: topsw0(KLON), toplw0(KLON), solsw0(KLON), sollw0(KLON) REAL, INTENT(out) :: sollwdown(KLON) REAL, INTENT(out) :: swdn(KLON,kflev+1),swdn0(KLON,kflev+1), swdnc0(KLON,kflev+1) REAL, INTENT(out) :: swup(KLON,kflev+1),swup0(KLON,kflev+1), swupc0(KLON,kflev+1) REAL, INTENT(out) :: lwdn(KLON,kflev+1),lwdn0(KLON,kflev+1), lwdnc0(KLON,kflev+1) REAL, INTENT(out) :: lwup(KLON,kflev+1),lwup0(KLON,kflev+1), lwupc0(KLON,kflev+1) REAL, INTENT(out) :: topswad_aero(KLON), solswad_aero(KLON) ! output: aerosol direct forcing at TOA and surface REAL, INTENT(out) :: topswai_aero(KLON), solswai_aero(KLON) ! output: aerosol indirect forcing atTOA and surface REAL, INTENT(out) :: toplwad_aero(KLON), sollwad_aero(KLON) ! output: LW aerosol direct forcing at TOA and surface REAL, INTENT(out) :: toplwai_aero(KLON), sollwai_aero(KLON) ! output: LW aerosol indirect forcing atTOA and surface REAL, DIMENSION(klon), INTENT(out) :: topswad0_aero REAL, DIMENSION(klon), INTENT(out) :: solswad0_aero REAL, DIMENSION(klon), INTENT(out) :: toplwad0_aero REAL, DIMENSION(klon), INTENT(out) :: sollwad0_aero REAL, DIMENSION(kdlon,9), INTENT(out) :: topsw_aero REAL, DIMENSION(kdlon,9), INTENT(out) :: topsw0_aero REAL, DIMENSION(kdlon,9), INTENT(out) :: solsw_aero REAL, DIMENSION(kdlon,9), INTENT(out) :: solsw0_aero REAL, DIMENSION(kdlon,3), INTENT(out) :: topswcf_aero REAL, DIMENSION(kdlon,3), INTENT(out) :: solswcf_aero REAL, DIMENSION(kdlon,kflev+1), INTENT(out) :: ZSWFT0_i REAL, DIMENSION(kdlon,kflev+1), INTENT(out) :: ZLWFT0_i ! Local variables REAL(KIND=8) ZFSUP(KDLON,KFLEV+1) REAL(KIND=8) ZFSDN(KDLON,KFLEV+1) REAL(KIND=8) ZFSUP0(KDLON,KFLEV+1) REAL(KIND=8) ZFSDN0(KDLON,KFLEV+1) REAL(KIND=8) ZFSUPC0(KDLON,KFLEV+1) REAL(KIND=8) ZFSDNC0(KDLON,KFLEV+1) REAL(KIND=8) ZFLUP(KDLON,KFLEV+1) REAL(KIND=8) ZFLDN(KDLON,KFLEV+1) REAL(KIND=8) ZFLUP0(KDLON,KFLEV+1) REAL(KIND=8) ZFLDN0(KDLON,KFLEV+1) REAL(KIND=8) ZFLUPC0(KDLON,KFLEV+1) REAL(KIND=8) ZFLDNC0(KDLON,KFLEV+1) REAL(KIND=8) zx_alpha1, zx_alpha2 INTEGER k, kk, i, j, iof, nb_gr INTEGER ist,iend,ktdia,kmode REAL(KIND=8) PSCT REAL(KIND=8) PALBD(kdlon,2), PALBP(kdlon,2) ! MPL 06.01.09: pour RRTM, creation de PALBD_NEW et PALBP_NEW ! avec NSW en deuxieme dimension REAL(KIND=8) PALBD_NEW(kdlon,NSW), PALBP_NEW(kdlon,NSW) REAL(KIND=8) PEMIS(kdlon), PDT0(kdlon), PVIEW(kdlon) REAL(KIND=8) PPSOL(kdlon), PDP(kdlon,KLEV) REAL(KIND=8) PTL(kdlon,kflev+1), PPMB(kdlon,kflev+1) REAL(KIND=8) PTAVE(kdlon,kflev) REAL(KIND=8) PWV(kdlon,kflev), PQS(kdlon,kflev) !!!!!!! Declarations specifiques pour ECRAD !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! ! AI 02.2021 #ifdef CPP_ECRAD ! ATTENTION les dimensions klon, kdlon ??? ! INPUTS REAL, DIMENSION(kdlon,kflev+1) :: ZSWFT0_ii, ZLWFT0_ii REAL(KIND=8) ZEMISW(klon), & ! LW emissivity inside the window region ZEMIS(klon) ! LW emissivity outside the window region REAL(KIND=8) ZGELAM(klon), & ! longitudes en rad ZGEMU(klon) ! sin(latitude) REAL(KIND=8) ZCO2, & ! CO2 mass mixing ratios on full levels ZCH4, & ! CH4 mass mixing ratios on full levels ZN2O, & ! N2O mass mixing ratios on full levels ZNO2, & ! NO2 mass mixing ratios on full levels ZCFC11, & ! CFC11 ZCFC12, & ! CFC12 ZHCFC22, & ! HCFC22 ZCCL4, & ! CCL4 ZO2 ! O2 REAL(KIND=8) ZQ_RAIN(klon,klev), & ! Rain cloud mass mixing ratio (kg/kg) ? ZQ_SNOW(klon,klev) ! Snow cloud mass mixing ratio (kg/kg) ? REAL(KIND=8) ZAEROSOL_OLD(KLON,6,KLEV), & ! ZAEROSOL(KLON,KLEV,naero_grp) ! ! OUTPUTS REAL(KIND=8) ZFLUX_DIR(klon), & ! Direct compt of surf flux into horizontal plane ZFLUX_DIR_CLEAR(klon), & ! CS Direct ZFLUX_DIR_INTO_SUN(klon), & ! ZFLUX_UV(klon), & ! UV flux ZFLUX_PAR(klon), & ! photosynthetically active radiation similarly ZFLUX_PAR_CLEAR(klon), & ! CS photosynthetically ZFLUX_SW_DN_TOA(klon), & ! DN SW flux at TOA ZEMIS_OUT(klon) ! effective broadband emissivity REAL(KIND=8) ZLWDERIVATIVE(klon,klev+1) ! LW derivatives REAL(KIND=8) ZSWDIFFUSEBAND(klon,NSW), & ! SW DN flux in diffuse albedo band ZSWDIRECTBAND(klon,NSW) ! SW DN flux in direct albedo band REAL(KIND=8) SOLARIRAD REAL(KIND=8) seuilmach ! AI 10 mars 22 : Pour les tests Offline logical :: lldebug_for_offline = .false. REAL(KIND=8) solaire_off(klon), & ZCO2_off(klon,klev), & ZCH4_off(klon,klev), & ! CH4 mass mixing ratios on full levels ZN2O_off(klon,klev), & ! N2O mass mixing ratios on full levels ZNO2_off(klon,klev), & ! NO2 mass mixing ratios on full levels ZCFC11_off(klon,klev), & ! CFC11 ZCFC12_off(klon,klev), & ! CFC12 ZHCFC22_off(klon,klev), & ! HCFC22 ZCCL4_off(klon,klev), & ! CCL4 ZO2_off(klon,klev) ! O2#endif #endif !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! REAL(kind=8) POZON(kdlon, kflev, size(wo, 3)) ! mass fraction of ozone ! "POZON(:, :, 1)" is for the average day-night field, ! "POZON(:, :, 2)" is for daylight time. !!!!! Modif MPL 6.01.09 avec RRTM, on passe de 5 a 6 REAL(KIND=8) PAER(kdlon,kflev,6) REAL(KIND=8) PCLDLD(kdlon,kflev) REAL(KIND=8) PCLDLU(kdlon,kflev) REAL(KIND=8) PCLDSW(kdlon,kflev) REAL(KIND=8) PTAU(kdlon,2,kflev) REAL(KIND=8) POMEGA(kdlon,2,kflev) REAL(KIND=8) PCG(kdlon,2,kflev) REAL(KIND=8) zfract(kdlon), zrmu0(kdlon), zdist REAL(KIND=8) zheat(kdlon,kflev), zcool(kdlon,kflev) REAL(KIND=8) zheat0(kdlon,kflev), zcool0(kdlon,kflev) REAL(KIND=8) zheat_volc(kdlon,kflev), zcool_volc(kdlon,kflev) !NL REAL(KIND=8) ztopsw(kdlon), ztoplw(kdlon) REAL(KIND=8) zsolsw(kdlon), zsollw(kdlon), zalbpla(kdlon), zsolswfdiff(kdlon) REAL(KIND=8) zsollwdown(kdlon) REAL(KIND=8) ztopsw0(kdlon), ztoplw0(kdlon) REAL(KIND=8) zsolsw0(kdlon), zsollw0(kdlon) REAL(KIND=8) zznormcp REAL(KIND=8) tauaero(kdlon,kflev,naero_grp,2) ! aer opt properties REAL(KIND=8) pizaero(kdlon,kflev,naero_grp,2) REAL(KIND=8) cgaero(kdlon,kflev,naero_grp,2) REAL(KIND=8) PTAUA(kdlon,2,kflev) ! present-day value of cloud opt thickness (PTAU is pre-industrial value), local use REAL(KIND=8) POMEGAA(kdlon,2,kflev) ! dito for single scatt albedo REAL(KIND=8) ztopswadaero(kdlon), zsolswadaero(kdlon) ! Aerosol direct forcing at TOAand surface REAL(KIND=8) ztopswad0aero(kdlon), zsolswad0aero(kdlon) ! Aerosol direct forcing at TOAand surface REAL(KIND=8) ztopswaiaero(kdlon), zsolswaiaero(kdlon) ! dito, indirect !--NL REAL(KIND=8) zswadaero(kdlon,kflev+1) ! SW Aerosol direct forcing REAL(KIND=8) zlwadaero(kdlon,kflev+1) ! LW Aerosol direct forcing REAL(KIND=8) volmip_solsw(kdlon) ! SW clear sky in the case of VOLMIP !-LW by CK REAL(KIND=8) ztoplwadaero(kdlon), zsollwadaero(kdlon) ! LW Aerosol direct forcing at TOAand surface REAL(KIND=8) ztoplwad0aero(kdlon), zsollwad0aero(kdlon) ! LW Aerosol direct forcing at TOAand surface REAL(KIND=8) ztoplwaiaero(kdlon), zsollwaiaero(kdlon) ! dito, indirect !-end REAL(KIND=8) ztopsw_aero(kdlon,9), ztopsw0_aero(kdlon,9) REAL(KIND=8) zsolsw_aero(kdlon,9), zsolsw0_aero(kdlon,9) REAL(KIND=8) ztopswcf_aero(kdlon,3), zsolswcf_aero(kdlon,3) ! real, parameter:: dobson_u = 2.1415e-05 ! Dobson unit, in kg m-2 deje declare dans physiq.F MPL 20130618 !MPL input supplementaires pour RECMWFL ! flwc, fiwc = Liquid Water Content & Ice Water Content (kg/kg) REAL(KIND=8) GEMU(klon) !MPL input RECMWFL: ! Tableaux aux niveaux inverses pour respecter convention Arpege REAL(KIND=8) ref_liq_i(klon,klev) ! cloud droplet radius present-day from newmicro (inverted) REAL(KIND=8) ref_ice_i(klon,klev) ! ice crystal radius present-day from newmicro (inverted) !--OB REAL(KIND=8) ref_liq_pi_i(klon,klev) ! cloud droplet radius pre-industrial from newmicro (inverted) REAL(KIND=8) ref_ice_pi_i(klon,klev) ! ice crystal radius pre-industrial from newmicro (inverted) !--end OB REAL(KIND=8) paprs_i(klon,klev+1) REAL(KIND=8) pplay_i(klon,klev) REAL(KIND=8) cldfra_i(klon,klev) REAL(KIND=8) POZON_i(kdlon,kflev, size(wo, 3)) ! mass fraction of ozone ! "POZON(:, :, 1)" is for the average day-night field, ! "POZON(:, :, 2)" is for daylight time. !!!!! Modif MPL 6.01.09 avec RRTM, on passe de 5 a 6 REAL(KIND=8) PAER_i(kdlon,kflev,6) REAL(KIND=8) PDP_i(klon,klev) REAL(KIND=8) t_i(klon,klev),q_i(klon,klev),qsat_i(klon,klev) REAL(KIND=8) flwc_i(klon,klev),fiwc_i(klon,klev) !MPL output RECMWFL: REAL(KIND=8) ZEMTD (klon,klev+1),ZEMTD_i (klon,klev+1) REAL(KIND=8) ZEMTU (klon,klev+1),ZEMTU_i (klon,klev+1) REAL(KIND=8) ZTRSO (klon,klev+1),ZTRSO_i (klon,klev+1) REAL(KIND=8) ZTH (klon,klev+1),ZTH_i (klon,klev+1) REAL(KIND=8) ZCTRSO(klon,2) REAL(KIND=8) ZCEMTR(klon,2) REAL(KIND=8) ZTRSOD(klon) REAL(KIND=8) ZLWFC (klon,2) REAL(KIND=8) ZLWFT (klon,klev+1),ZLWFT_i (klon,klev+1) REAL(KIND=8) ZSWFC (klon,2) REAL(KIND=8) ZSWFT (klon,klev+1),ZSWFT_i (klon,klev+1) REAL(KIND=8) ZFLUCDWN_i(klon,klev+1),ZFLUCUP_i(klon,klev+1) REAL(KIND=8) PPIZA_TOT(klon,klev,NSW) REAL(KIND=8) PCGA_TOT(klon,klev,NSW) REAL(KIND=8) PTAU_TOT(klon,klev,NSW) REAL(KIND=8) PPIZA_NAT(klon,klev,NSW) REAL(KIND=8) PCGA_NAT(klon,klev,NSW) REAL(KIND=8) PTAU_NAT(klon,klev,NSW) #ifdef CPP_RRTM REAL(KIND=8) PTAU_LW_TOT(klon,klev,NLW) REAL(KIND=8) PTAU_LW_NAT(klon,klev,NLW) #endif REAL(KIND=8) PSFSWDIR(klon,NSW) REAL(KIND=8) PSFSWDIF(klon,NSW) REAL(KIND=8) PFSDNN(klon) REAL(KIND=8) PFSDNV(klon) !MPL On ne redefinit pas les tableaux ZFLUX,ZFLUC, !MPL ZFSDWN,ZFCDWN,ZFSUP,ZFCUP car ils existent deja !MPL sous les noms de ZFLDN,ZFLDN0,ZFLUP,ZFLUP0, !MPL ZFSDN,ZFSDN0,ZFSUP,ZFSUP0 REAL(KIND=8) ZFLUX_i (klon,2,klev+1) REAL(KIND=8) ZFLUC_i (klon,2,klev+1) REAL(KIND=8) ZFSDWN_i (klon,klev+1) REAL(KIND=8) ZFCDWN_i (klon,klev+1) REAL(KIND=8) ZFCCDWN_i (klon,klev+1) REAL(KIND=8) ZFSUP_i (klon,klev+1) REAL(KIND=8) ZFCUP_i (klon,klev+1) REAL(KIND=8) ZFCCUP_i (klon,klev+1) REAL(KIND=8) ZFLCCDWN_i (klon,klev+1) REAL(KIND=8) ZFLCCUP_i (klon,klev+1) ! 3 lignes suivantes a activer pour CCMVAL (MPL 20100412) ! REAL(KIND=8) RSUN(3,2) ! REAL(KIND=8) SUN(3) ! REAL(KIND=8) SUN_FRACT(2) REAL, PARAMETER:: dobson_u = 2.1415e-05 ! Dobson unit, in kg m-2 CHARACTER (LEN=80) :: abort_message CHARACTER (LEN=80) :: modname='radlwsw_m' REAL zdir, zdif ! ========= INITIALISATIONS ============================================== IF (lldebug) THEN print*,'Entree dans radlwsw ' print*,'************* INITIALISATIONS *****************************' print*,'klon, kdlon, klev, kflev =',klon, kdlon, klev, kflev ENDIF CALL assert(size(wo, 1) == klon, size(wo, 2) == klev, "radlwsw wo") ist=1 iend=klon ktdia=1 kmode=ist ! Aeros tauaero(:,:,:,:)=0. pizaero(:,:,:,:)=0. cgaero(:,:,:,:)=0. ! lldebug=.FALSE. ztopsw_aero(:,:) = 0. !ym missing init : warning : not initialized in SW_AEROAR4 ztopsw0_aero(:,:) = 0. !ym missing init : warning : not initialized in SW_AEROAR4 zsolsw_aero(:,:) = 0. !ym missing init : warning : not initialized in SW_AEROAR4 zsolsw0_aero(:,:) = 0. !ym missing init : warning : not initialized in SW_AEROAR4 ZTOPSWADAERO(:) = 0. !ym missing init ZSOLSWADAERO(:) = 0. !ym missing init ZTOPSWAD0AERO(:) = 0. !ym missing init ZSOLSWAD0AERO(:) = 0. !ym missing init ZTOPSWAIAERO(:) = 0. !ym missing init ZSOLSWAIAERO(:) = 0. !ym missing init ZTOPSWCF_AERO(:,:)= 0.!ym missing init ZSOLSWCF_AERO(:,:) =0. !ym missing init ! ! AI 02.2021 #ifdef CPP_ECRAD ZEMIS = 1.0 ZEMISW = 1.0 ZGELAM = longitude ZGEMU = sin(latitude) ZCO2 = RCO2 ZCH4 = RCH4 ZN2O = RN2O ZNO2 = 0.0 ZCFC11 = RCFC11 ZCFC12 = RCFC12 ZHCFC22 = 0.0 ZO2 = 0.0 ZCCL4 = 0.0 ZQ_RAIN = 0.0 ZQ_SNOW = 0.0 ZAEROSOL_OLD = 0.0 ZAEROSOL = 0.0 seuilmach=tiny(seuilmach) #endif !------------------------------------------- nb_gr = KLON / kdlon IF (nb_gr*kdlon .NE. KLON) THEN PRINT*, "kdlon mauvais:", KLON, kdlon, nb_gr call abort_physic("radlwsw", "", 1) ENDIF IF (kflev .NE. KLEV) THEN PRINT*, "kflev differe de KLEV, kflev, KLEV" call abort_physic("radlwsw", "", 1) ENDIF !------------------------------------------- DO k = 1, KLEV DO i = 1, KLON heat(i,k)=0. cool(i,k)=0. heat_volc(i,k)=0. !NL cool_volc(i,k)=0. !NL heat0(i,k)=0. cool0(i,k)=0. ENDDO ENDDO ! zdist = dist ! PSCT = solaire/zdist/zdist IF (type_trac == 'repr') THEN #ifdef REPROBUS IF (iflag_rrtm==0) THEN IF (ok_SUNTIME) PSCT = solaireTIME/zdist/zdist print*,'Constante solaire: ',PSCT*zdist*zdist ENDIF #endif ENDIF IF (lldebug) THEN print*,'************** Debut boucle de 1 a ', nb_gr ENDIF DO j = 1, nb_gr iof = kdlon*(j-1) DO i = 1, kdlon zfract(i) = fract(iof+i) zrmu0(i) = rmu0(iof+i) IF (iflag_rrtm==0) THEN ! Albedo PALBD(i,1)=alb_dif(iof+i,1) PALBD(i,2)=alb_dif(iof+i,2) PALBP(i,1)=alb_dir(iof+i,1) PALBP(i,2)=alb_dir(iof+i,2) ! AI 02.2021 cas iflag_rrtm=1 et 2 ELSEIF (iflag_rrtm==1.OR.iflag_rrtm==2) THEN DO kk=1,NSW PALBD_NEW(i,kk)=alb_dif(iof+i,kk) PALBP_NEW(i,kk)=alb_dir(iof+i,kk) ENDDO ! ENDIF !albedo SB <<< PEMIS(i) = 1.0 !!!!! A REVOIR (MPL) PVIEW(i) = 1.66 PPSOL(i) = paprs(iof+i,1) zx_alpha1 = (paprs(iof+i,1)-pplay(iof+i,2))/(pplay(iof+i,1)-pplay(iof+i,2)) zx_alpha2 = 1.0 - zx_alpha1 PTL(i,1) = t(iof+i,1) * zx_alpha1 + t(iof+i,2) * zx_alpha2 PTL(i,KLEV+1) = t(iof+i,KLEV) PDT0(i) = tsol(iof+i) - PTL(i,1) ENDDO DO k = 2, kflev DO i = 1, kdlon PTL(i,k) = (t(iof+i,k)+t(iof+i,k-1))*0.5 ENDDO ENDDO DO k = 1, kflev DO i = 1, kdlon PDP(i,k) = paprs(iof+i,k)-paprs(iof+i,k+1) PTAVE(i,k) = t(iof+i,k) PWV(i,k) = MAX (q(iof+i,k), 1.0e-12) PQS(i,k) = PWV(i,k) ! Confert from column density of ozone in a cell, in kDU, to a mass fraction POZON(i,k, :) = wo(iof+i, k, :) * RG * dobson_u * 1e3 & / (paprs(iof+i, k) - paprs(iof+i, k+1)) ! A activer pour CCMVAL on prend l'ozone impose (MPL 07042010) ! POZON(i,k,:) = wo(i,k,:) ! print *,'RADLWSW: POZON',k, POZON(i,k,1) PCLDLD(i,k) = cldfra(iof+i,k)*cldemi(iof+i,k) PCLDLU(i,k) = cldfra(iof+i,k)*cldemi(iof+i,k) PCLDSW(i,k) = cldfra(iof+i,k) PTAU(i,1,k) = MAX(cldtaupi(iof+i,k), 1.0e-05)! 1e-12 serait instable PTAU(i,2,k) = MAX(cldtaupi(iof+i,k), 1.0e-05)! pour 32-bit machines POMEGA(i,1,k) = 0.9999 - 5.0e-04 * EXP(-0.5 * PTAU(i,1,k)) POMEGA(i,2,k) = 0.9988 - 2.5e-03 * EXP(-0.05 * PTAU(i,2,k)) PCG(i,1,k) = 0.865 PCG(i,2,k) = 0.910 !- ! Introduced for aerosol indirect forcings. ! The following values use the cloud optical thickness calculated from ! present-day aerosol concentrations whereas the quantities without the ! "A" at the end are for pre-industial (natural-only) aerosol concentrations ! PTAUA(i,1,k) = MAX(cldtaupd(iof+i,k), 1.0e-05)! 1e-12 serait instable PTAUA(i,2,k) = MAX(cldtaupd(iof+i,k), 1.0e-05)! pour 32-bit machines POMEGAA(i,1,k) = 0.9999 - 5.0e-04 * EXP(-0.5 * PTAUA(i,1,k)) POMEGAA(i,2,k) = 0.9988 - 2.5e-03 * EXP(-0.05 * PTAUA(i,2,k)) ENDDO ENDDO IF (type_trac == 'repr') THEN #ifdef REPROBUS ndimozon = size(wo, 3) CALL RAD_INTERACTIF(POZON,iof) #endif ENDIF ! DO k = 1, kflev+1 DO i = 1, kdlon PPMB(i,k) = paprs(iof+i,k)/100.0 ENDDO ENDDO ! !!!!! Modif MPL 6.01.09 avec RRTM, on passe de 5 a 6 DO kk = 1, 6 DO k = 1, kflev DO i = 1, kdlon PAER(i,k,kk) = 1.0E-15 !!!!! A REVOIR (MPL) ENDDO ENDDO ENDDO DO k = 1, kflev DO i = 1, kdlon tauaero(i,k,:,1)=tau_aero(iof+i,k,:,1) pizaero(i,k,:,1)=piz_aero(iof+i,k,:,1) cgaero(i,k,:,1) =cg_aero(iof+i,k,:,1) tauaero(i,k,:,2)=tau_aero(iof+i,k,:,2) pizaero(i,k,:,2)=piz_aero(iof+i,k,:,2) cgaero(i,k,:,2) =cg_aero(iof+i,k,:,2) ENDDO ENDDO ! !===== iflag_rrtm ================================================ ! IF (iflag_rrtm == 0) THEN !!!! remettre 0 juste pour tester l'ancien rayt via rrtm ! !--- Mise a zero des tableaux output du rayonnement LW-AR4 ---------- DO k = 1, kflev+1 DO i = 1, kdlon ! print *,'RADLWSW: boucle mise a zero i k',i,k ZFLUP(i,k)=0. ZFLDN(i,k)=0. ZFLUP0(i,k)=0. ZFLDN0(i,k)=0. ZLWFT0_i(i,k)=0. ZFLUCUP_i(i,k)=0. ZFLUCDWN_i(i,k)=0. ENDDO ENDDO DO k = 1, kflev DO i = 1, kdlon zcool(i,k)=0. zcool_volc(i,k)=0. !NL zcool0(i,k)=0. ENDDO ENDDO DO i = 1, kdlon ztoplw(i)=0. zsollw(i)=0. ztoplw0(i)=0. zsollw0(i)=0. zsollwdown(i)=0. ENDDO ! Old radiation scheme, used for AR4 runs ! average day-night ozone for longwave CALL LW_LMDAR4(& PPMB, PDP,& PPSOL,PDT0,PEMIS,& PTL, PTAVE, PWV, POZON(:, :, 1), PAER,& PCLDLD,PCLDLU,& PVIEW,& zcool, zcool0,& ztoplw,zsollw,ztoplw0,zsollw0,& zsollwdown,& ZFLUP, ZFLDN, ZFLUP0,ZFLDN0) !----- Mise a zero des tableaux output du rayonnement SW-AR4 DO k = 1, kflev+1 DO i = 1, kdlon ZFSUP(i,k)=0. ZFSDN(i,k)=0. ZFSUP0(i,k)=0. ZFSDN0(i,k)=0. ZFSUPC0(i,k)=0. ZFSDNC0(i,k)=0. ZFLUPC0(i,k)=0. ZFLDNC0(i,k)=0. ZSWFT0_i(i,k)=0. ZFCUP_i(i,k)=0. ZFCDWN_i(i,k)=0. ZFCCUP_i(i,k)=0. ZFCCDWN_i(i,k)=0. ZFLCCUP_i(i,k)=0. ZFLCCDWN_i(i,k)=0. zswadaero(i,k)=0. !--NL ENDDO ENDDO DO k = 1, kflev DO i = 1, kdlon zheat(i,k)=0. zheat_volc(i,k)=0. zheat0(i,k)=0. ENDDO ENDDO DO i = 1, kdlon zalbpla(i)=0. ztopsw(i)=0. zsolsw(i)=0. ztopsw0(i)=0. zsolsw0(i)=0. ztopswadaero(i)=0. zsolswadaero(i)=0. ztopswaiaero(i)=0. zsolswaiaero(i)=0. ENDDO !--fraction of diffuse radiation in surface SW downward radiation !--not computed with old radiation scheme zsolswfdiff(:) = -999.999 ! print *,'Avant SW_LMDAR4: PSCT zrmu0 zfract',PSCT, zrmu0, zfract ! daylight ozone, if we have it, for short wave CALL SW_AEROAR4(PSCT, zrmu0, zfract,& PPMB, PDP,& PPSOL, PALBD, PALBP,& PTAVE, PWV, PQS, POZON(:, :, size(wo, 3)), PAER,& PCLDSW, PTAU, POMEGA, PCG,& zheat, zheat0,& zalbpla,ztopsw,zsolsw,ztopsw0,zsolsw0,& ZFSUP,ZFSDN,ZFSUP0,ZFSDN0,& tauaero, pizaero, cgaero, & PTAUA, POMEGAA,& ztopswadaero,zsolswadaero,& ztopswad0aero,zsolswad0aero,& ztopswaiaero,zsolswaiaero, & ztopsw_aero,ztopsw0_aero,& zsolsw_aero,zsolsw0_aero,& ztopswcf_aero,zsolswcf_aero, & ok_ade, ok_aie, flag_aerosol,flag_aerosol_strat) ZSWFT0_i(:,:) = ZFSDN0(:,:)-ZFSUP0(:,:) ZLWFT0_i(:,:) =-ZFLDN0(:,:)-ZFLUP0(:,:) DO i=1,kdlon DO k=1,kflev+1 lwdn0 ( iof+i,k) = ZFLDN0 ( i,k) lwdn ( iof+i,k) = ZFLDN ( i,k) lwup0 ( iof+i,k) = ZFLUP0 ( i,k) lwup ( iof+i,k) = ZFLUP ( i,k) swdn0 ( iof+i,k) = ZFSDN0 ( i,k) swdn ( iof+i,k) = ZFSDN ( i,k) swup0 ( iof+i,k) = ZFSUP0 ( i,k) swup ( iof+i,k) = ZFSUP ( i,k) ENDDO ENDDO ! ELSE IF (iflag_rrtm == 1) then #ifdef CPP_RRTM ! if (prt_level.gt.10)write(lunout,*)'CPP_RRTM=.T.' !===== iflag_rrtm=1, on passe dans SW via RECMWFL =============== DO k = 1, kflev+1 DO i = 1, kdlon ZEMTD_i(i,k)=0. ZEMTU_i(i,k)=0. ZTRSO_i(i,k)=0. ZTH_i(i,k)=0. ZLWFT_i(i,k)=0. ZSWFT_i(i,k)=0. ZFLUX_i(i,1,k)=0. ZFLUX_i(i,2,k)=0. ZFLUC_i(i,1,k)=0. ZFLUC_i(i,2,k)=0. ZFSDWN_i(i,k)=0. ZFCDWN_i(i,k)=0. ZFCCDWN_i(i,k)=0. ZFSUP_i(i,k)=0. ZFCUP_i(i,k)=0. ZFCCUP_i(i,k)=0. ZFLCCDWN_i(i,k)=0. ZFLCCUP_i(i,k)=0. ENDDO ENDDO ! !--OB !--aerosol TOT - anthropogenic+natural - index 2 !--aerosol NAT - natural only - index 1 ! DO i = 1, kdlon DO k = 1, kflev DO kk=1, NSW ! PTAU_TOT(i,kflev+1-k,kk)=tau_aero_sw_rrtm(i,k,2,kk) PPIZA_TOT(i,kflev+1-k,kk)=piz_aero_sw_rrtm(i,k,2,kk) PCGA_TOT(i,kflev+1-k,kk)=cg_aero_sw_rrtm(i,k,2,kk) ! PTAU_NAT(i,kflev+1-k,kk)=tau_aero_sw_rrtm(i,k,1,kk) PPIZA_NAT(i,kflev+1-k,kk)=piz_aero_sw_rrtm(i,k,1,kk) PCGA_NAT(i,kflev+1-k,kk)=cg_aero_sw_rrtm(i,k,1,kk) ! ENDDO ENDDO ENDDO !-end OB ! !--C. Kleinschmitt !--aerosol TOT - anthropogenic+natural - index 2 !--aerosol NAT - natural only - index 1 ! DO i = 1, kdlon DO k = 1, kflev DO kk=1, NLW ! PTAU_LW_TOT(i,kflev+1-k,kk)=tau_aero_lw_rrtm(i,k,2,kk) PTAU_LW_NAT(i,kflev+1-k,kk)=tau_aero_lw_rrtm(i,k,1,kk) ! ENDDO ENDDO ENDDO !-end C. Kleinschmitt ! DO i = 1, kdlon ZCTRSO(i,1)=0. ZCTRSO(i,2)=0. ZCEMTR(i,1)=0. ZCEMTR(i,2)=0. ZTRSOD(i)=0. ZLWFC(i,1)=0. ZLWFC(i,2)=0. ZSWFC(i,1)=0. ZSWFC(i,2)=0. PFSDNN(i)=0. PFSDNV(i)=0. DO kk = 1, NSW PSFSWDIR(i,kk)=0. PSFSWDIF(i,kk)=0. ENDDO ENDDO !----- Fin des mises a zero des tableaux output de RECMWF ------------------- ! GEMU(1:klon)=sin(rlatd(1:klon)) ! On met les donnees dans l'ordre des niveaux arpege paprs_i(:,1)=paprs(:,klev+1) DO k=1,klev paprs_i(1:klon,k+1) =paprs(1:klon,klev+1-k) pplay_i(1:klon,k) =pplay(1:klon,klev+1-k) cldfra_i(1:klon,k) =cldfra(1:klon,klev+1-k) PDP_i(1:klon,k) =PDP(1:klon,klev+1-k) t_i(1:klon,k) =t(1:klon,klev+1-k) q_i(1:klon,k) =q(1:klon,klev+1-k) qsat_i(1:klon,k) =qsat(1:klon,klev+1-k) flwc_i(1:klon,k) =flwc(1:klon,klev+1-k) fiwc_i(1:klon,k) =fiwc(1:klon,klev+1-k) ref_liq_i(1:klon,k) =ref_liq(1:klon,klev+1-k) ref_ice_i(1:klon,k) =ref_ice(1:klon,klev+1-k) !-OB ref_liq_pi_i(1:klon,k) =ref_liq_pi(1:klon,klev+1-k) ref_ice_pi_i(1:klon,k) =ref_ice_pi(1:klon,klev+1-k) ENDDO DO k=1,kflev POZON_i(1:klon,k,:)=POZON(1:klon,kflev+1-k,:) !!! POZON_i(1:klon,k)=POZON(1:klon,k) !!! on laisse 1=sol et klev=top ! print *,'Juste avant RECMWFL: k tsol temp',k,tsol,t(1,k) !!!!!!! Modif MPL 6.01.09 avec RRTM, on passe de 5 a 6 DO i=1,6 PAER_i(1:klon,k,i)=PAER(1:klon,kflev+1-k,i) ENDDO ENDDO ! print *,'RADLWSW: avant RECMWFL, RI0,rmu0=',solaire,rmu0 ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! La version ARPEGE1D utilise differentes valeurs de la constante ! solaire suivant le rayonnement utilise. ! A controler ... ! SOLAR FLUX AT THE TOP (/YOMPHY3/) ! introduce season correction !-------------------------------------- ! RII0 = RIP0 ! IF(LRAYFM) ! RII0 = RIP0M ! =rip0m if Morcrette non-each time step call. ! IF(LRAYFM15) ! RII0 = RIP0M15 ! =rip0m if Morcrette non-each time step call. RII0=solaire/zdist/zdist ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Ancien appel a RECMWF (celui du cy25) ! CALL RECMWF (ist , iend, klon , ktdia , klev , kmode , ! s PALBD , PALBP , paprs_i , pplay_i , RCO2 , cldfra_i, ! s POZON_i , PAER_i , PDP_i , PEMIS , GEMU , rmu0, ! s q_i , qsat_i , fiwc_i , flwc_i , zmasq , t_i ,tsol, ! s ZEMTD_i , ZEMTU_i , ZTRSO_i , ! s ZTH_i , ZCTRSO , ZCEMTR , ZTRSOD , ! s ZLWFC , ZLWFT_i , ZSWFC , ZSWFT_i , ! s ZFLUX_i , ZFLUC_i , ZFSDWN_i, ZFSUP_i , ZFCDWN_i,ZFCUP_i) ! s 'RECMWF ') ! IF (lldebug) THEN CALL writefield_phy('paprs_i',paprs_i,klev+1) CALL writefield_phy('pplay_i',pplay_i,klev) CALL writefield_phy('cldfra_i',cldfra_i,klev) CALL writefield_phy('pozon_i',POZON_i,klev) CALL writefield_phy('paer_i',PAER_i,klev) CALL writefield_phy('pdp_i',PDP_i,klev) CALL writefield_phy('q_i',q_i,klev) CALL writefield_phy('qsat_i',qsat_i,klev) CALL writefield_phy('fiwc_i',fiwc_i,klev) CALL writefield_phy('flwc_i',flwc_i,klev) CALL writefield_phy('t_i',t_i,klev) CALL writefield_phy('palbd_new',PALBD_NEW,NSW) CALL writefield_phy('palbp_new',PALBP_NEW,NSW) ENDIF ! Nouvel appel a RECMWF (celui du cy32t0) CALL RECMWF_AERO (ist , iend, klon , ktdia , klev , kmode ,& PALBD_NEW,PALBP_NEW, paprs_i , pplay_i , RCO2 , cldfra_i,& POZON_i , PAER_i , PDP_i , PEMIS , rmu0 ,& q_i , qsat_i , fiwc_i , flwc_i , zmasq , t_i ,tsol,& ref_liq_i, ref_ice_i, & ref_liq_pi_i, ref_ice_pi_i, & ! rajoute par OB pour diagnostiquer effet indirect ZEMTD_i , ZEMTU_i , ZTRSO_i ,& ZTH_i , ZCTRSO , ZCEMTR , ZTRSOD ,& ZLWFC , ZLWFT_i , ZSWFC , ZSWFT_i ,& PSFSWDIR , PSFSWDIF, PFSDNN , PFSDNV ,& PPIZA_TOT, PCGA_TOT,PTAU_TOT,& PPIZA_NAT, PCGA_NAT,PTAU_NAT, & ! rajoute par OB pour diagnostiquer effet direct PTAU_LW_TOT, PTAU_LW_NAT, & ! rajoute par C. Kleinschmitt ZFLUX_i , ZFLUC_i ,& ZFSDWN_i , ZFSUP_i , ZFCDWN_i, ZFCUP_i, ZFCCDWN_i, ZFCCUP_i, ZFLCCDWN_i, ZFLCCUP_i, & ZTOPSWADAERO,ZSOLSWADAERO,& ! rajoute par OB pour diagnostics ZTOPSWAD0AERO,ZSOLSWAD0AERO,& ZTOPSWAIAERO,ZSOLSWAIAERO, & ZTOPSWCF_AERO,ZSOLSWCF_AERO, & ZSWADAERO, & !--NL ZTOPLWADAERO,ZSOLLWADAERO,& ! rajoute par C. Kleinscmitt pour LW diagnostics ZTOPLWAD0AERO,ZSOLLWAD0AERO,& ZTOPLWAIAERO,ZSOLLWAIAERO, & ZLWADAERO, & !--NL volmip_solsw, flag_volc_surfstrat, & !--VOLMIP ok_ade, ok_aie, ok_volcan, flag_aerosol,flag_aerosol_strat, flag_aer_feedback) ! flags aerosols !--OB diagnostics ! & PTOPSWAIAERO,PSOLSWAIAERO,& ! & PTOPSWCFAERO,PSOLSWCFAERO,& ! & PSWADAERO,& !--NL !!--LW diagnostics CK ! & PTOPLWADAERO,PSOLLWADAERO,& ! & PTOPLWAD0AERO,PSOLLWAD0AERO,& ! & PTOPLWAIAERO,PSOLLWAIAERO,& ! & PLWADAERO,& !--NL !!..end ! & ok_ade, ok_aie, ok_volcan, flag_aerosol,flag_aerosol_strat,& ! & flag_aer_feedback) ! print *,'RADLWSW: apres RECMWF' IF (lldebug) THEN CALL writefield_phy('zemtd_i',ZEMTD_i,klev+1) CALL writefield_phy('zemtu_i',ZEMTU_i,klev+1) CALL writefield_phy('ztrso_i',ZTRSO_i,klev+1) CALL writefield_phy('zth_i',ZTH_i,klev+1) CALL writefield_phy('zctrso',ZCTRSO,2) CALL writefield_phy('zcemtr',ZCEMTR,2) CALL writefield_phy('ztrsod',ZTRSOD,1) CALL writefield_phy('zlwfc',ZLWFC,2) CALL writefield_phy('zlwft_i',ZLWFT_i,klev+1) CALL writefield_phy('zswfc',ZSWFC,2) CALL writefield_phy('zswft_i',ZSWFT_i,klev+1) CALL writefield_phy('psfswdir',PSFSWDIR,6) CALL writefield_phy('psfswdif',PSFSWDIF,6) CALL writefield_phy('pfsdnn',PFSDNN,1) CALL writefield_phy('pfsdnv',PFSDNV,1) CALL writefield_phy('ppiza_dst',PPIZA_TOT,klev) CALL writefield_phy('pcga_dst',PCGA_TOT,klev) CALL writefield_phy('ptaurel_dst',PTAU_TOT,klev) CALL writefield_phy('zflux_i',ZFLUX_i,klev+1) CALL writefield_phy('zfluc_i',ZFLUC_i,klev+1) CALL writefield_phy('zfsdwn_i',ZFSDWN_i,klev+1) CALL writefield_phy('zfsup_i',ZFSUP_i,klev+1) CALL writefield_phy('zfcdwn_i',ZFCDWN_i,klev+1) CALL writefield_phy('zfcup_i',ZFCUP_i,klev+1) ENDIF ! --------- ! --------- ! On retablit l'ordre des niveaux lmd pour les tableaux de sortie ! D autre part, on multiplie les resultats SW par fract pour etre coherent ! avec l ancien rayonnement AR4. Si nuit, fract=0 donc pas de ! rayonnement SW. (MPL 260609) DO k=0,klev DO i=1,klon ZEMTD(i,k+1) = ZEMTD_i(i,k+1) ZEMTU(i,k+1) = ZEMTU_i(i,k+1) ZTRSO(i,k+1) = ZTRSO_i(i,k+1) ZTH(i,k+1) = ZTH_i(i,k+1) ! ZLWFT(i,k+1) = ZLWFT_i(i,klev+1-k) ! ZSWFT(i,k+1) = ZSWFT_i(i,klev+1-k) ZFLUP(i,k+1) = ZFLUX_i(i,1,k+1) ZFLDN(i,k+1) = ZFLUX_i(i,2,k+1) ZFLUP0(i,k+1) = ZFLUC_i(i,1,k+1) ZFLDN0(i,k+1) = ZFLUC_i(i,2,k+1) ZFSDN(i,k+1) = ZFSDWN_i(i,k+1)*fract(i) ZFSDN0(i,k+1) = ZFCDWN_i(i,k+1)*fract(i) ZFSDNC0(i,k+1)= ZFCCDWN_i(i,k+1)*fract(i) ZFSUP (i,k+1) = ZFSUP_i(i,k+1)*fract(i) ZFSUP0(i,k+1) = ZFCUP_i(i,k+1)*fract(i) ZFSUPC0(i,k+1)= ZFCCUP_i(i,k+1)*fract(i) ZFLDNC0(i,k+1)= ZFLCCDWN_i(i,k+1) ZFLUPC0(i,k+1)= ZFLCCUP_i(i,k+1) IF (ok_volcan) THEN ZSWADAERO(i,k+1)=ZSWADAERO(i,k+1)*fract(i) !--NL ENDIF ! Nouveau calcul car visiblement ZSWFT et ZSWFC sont nuls dans RRTM cy32 ! en sortie de radlsw.F90 - MPL 7.01.09 ZSWFT(i,k+1) = (ZFSDWN_i(i,k+1)-ZFSUP_i(i,k+1))*fract(i) ZSWFT0_i(i,k+1) = (ZFCDWN_i(i,k+1)-ZFCUP_i(i,k+1))*fract(i) ! WRITE(*,'("FSDN FSUP FCDN FCUP: ",4E12.5)') ZFSDWN_i(i,k+1),& ! ZFSUP_i(i,k+1),ZFCDWN_i(i,k+1),ZFCUP_i(i,k+1) ZLWFT(i,k+1) =-ZFLUX_i(i,2,k+1)-ZFLUX_i(i,1,k+1) ZLWFT0_i(i,k+1)=-ZFLUC_i(i,2,k+1)-ZFLUC_i(i,1,k+1) ! print *,'FLUX2 FLUX1 FLUC2 FLUC1',ZFLUX_i(i,2,k+1),& ! & ZFLUX_i(i,1,k+1),ZFLUC_i(i,2,k+1),ZFLUC_i(i,1,k+1) ENDDO ENDDO !--ajout OB ZTOPSWADAERO(:) =ZTOPSWADAERO(:) *fract(:) ZSOLSWADAERO(:) =ZSOLSWADAERO(:) *fract(:) ZTOPSWAD0AERO(:)=ZTOPSWAD0AERO(:)*fract(:) ZSOLSWAD0AERO(:)=ZSOLSWAD0AERO(:)*fract(:) ZTOPSWAIAERO(:) =ZTOPSWAIAERO(:) *fract(:) ZSOLSWAIAERO(:) =ZSOLSWAIAERO(:) *fract(:) ZTOPSWCF_AERO(:,1)=ZTOPSWCF_AERO(:,1)*fract(:) ZTOPSWCF_AERO(:,2)=ZTOPSWCF_AERO(:,2)*fract(:) ZTOPSWCF_AERO(:,3)=ZTOPSWCF_AERO(:,3)*fract(:) ZSOLSWCF_AERO(:,1)=ZSOLSWCF_AERO(:,1)*fract(:) ZSOLSWCF_AERO(:,2)=ZSOLSWCF_AERO(:,2)*fract(:) ZSOLSWCF_AERO(:,3)=ZSOLSWCF_AERO(:,3)*fract(:) ! --------- ! --------- ! On renseigne les champs LMDz, pour avoir la meme chose qu'en sortie de ! LW_LMDAR4 et SW_LMDAR4 !--fraction of diffuse radiation in surface SW downward radiation DO i = 1, kdlon IF (fract(i).GT.0.0) THEN zdir=SUM(PSFSWDIR(i,:)) zdif=SUM(PSFSWDIF(i,:)) zsolswfdiff(i) = zdif/(zdir+zdif) ELSE !--night zsolswfdiff(i) = 1.0 ENDIF ENDDO ! DO i = 1, kdlon zsolsw(i) = ZSWFT(i,1) zsolsw0(i) = ZSWFT0_i(i,1) ! zsolsw0(i) = ZFSDN0(i,1) -ZFSUP0(i,1) ztopsw(i) = ZSWFT(i,klev+1) ztopsw0(i) = ZSWFT0_i(i,klev+1) ! ztopsw0(i) = ZFSDN0(i,klev+1)-ZFSUP0(i,klev+1) ! ! zsollw(i) = ZFLDN(i,1) -ZFLUP(i,1) ! zsollw0(i) = ZFLDN0(i,1) -ZFLUP0(i,1) ! ztoplw(i) = ZFLDN(i,klev+1) -ZFLUP(i,klev+1) ! ztoplw0(i) = ZFLDN0(i,klev+1)-ZFLUP0(i,klev+1) zsollw(i) = ZLWFT(i,1) zsollw0(i) = ZLWFT0_i(i,1) ztoplw(i) = ZLWFT(i,klev+1)*(-1) ztoplw0(i) = ZLWFT0_i(i,klev+1)*(-1) ! IF (fract(i) == 0.) THEN !!!!! A REVOIR MPL (20090630) ca n a pas de sens quand fract=0 ! pas plus que dans le sw_AR4 zalbpla(i) = 1.0e+39 ELSE zalbpla(i) = ZFSUP(i,klev+1)/ZFSDN(i,klev+1) ENDIF !!! 5 juin 2015 !!! Correction MP bug RRTM zsollwdown(i)= -1.*ZFLDN(i,1) ENDDO ! print*,'OK2' !--add VOLMIP (surf cool or strat heat activate) IF (flag_volc_surfstrat > 0) THEN DO i = 1, kdlon zsolsw(i) = volmip_solsw(i)*fract(i) ENDDO ENDIF ! extrait de SW_AR4 ! DO k = 1, KFLEV ! kpl1 = k+1 ! DO i = 1, KDLON ! PHEAT(i,k) = -(ZFSUP(i,kpl1)-ZFSUP(i,k)) -(ZFSDN(i,k)-ZFSDN(i,kpl1)) ! PHEAT(i,k) = PHEAT(i,k) * RDAY*RG/RCPD / PDP(i,k) ! ZLWFT(klon,k),ZSWFT DO k=1,kflev DO i=1,kdlon zheat(i,k)=(ZSWFT(i,k+1)-ZSWFT(i,k))*RDAY*RG/RCPD/PDP(i,k) zheat0(i,k)=(ZSWFT0_i(i,k+1)-ZSWFT0_i(i,k))*RDAY*RG/RCPD/PDP(i,k) zcool(i,k)=(ZLWFT(i,k)-ZLWFT(i,k+1))*RDAY*RG/RCPD/PDP(i,k) zcool0(i,k)=(ZLWFT0_i(i,k)-ZLWFT0_i(i,k+1))*RDAY*RG/RCPD/PDP(i,k) IF (ok_volcan) THEN zheat_volc(i,k)=(ZSWADAERO(i,k+1)-ZSWADAERO(i,k))*RG/RCPD/PDP(i,k) !NL zcool_volc(i,k)=(ZLWADAERO(i,k)-ZLWADAERO(i,k+1))*RG/RCPD/PDP(i,k) !NL ENDIF ! print *,'heat cool heat0 cool0 ',zheat(i,k),zcool(i,k),zheat0(i,k),zcool0(i,k) ! ZFLUCUP_i(i,k)=ZFLUC_i(i,1,k) ! ZFLUCDWN_i(i,k)=ZFLUC_i(i,2,k) ENDDO ENDDO #else abort_message="You should compile with -rrtm if running with iflag_rrtm=1" call abort_physic(modname, abort_message, 1) #endif !====================================================================== ! AI fev 2021 ELSE IF(iflag_rrtm == 2) THEN print*,'Traitement cas iflag_rrtm = ',iflag_rrtm ! print*,'Mise a zero des flux ' #ifdef CPP_ECRAD DO k = 1, kflev+1 DO i = 1, kdlon ZEMTD_i(i,k)=0. ZEMTU_i(i,k)=0. ZTRSO_i(i,k)=0. ZTH_i(i,k)=0. ZLWFT_i(i,k)=0. ZSWFT_i(i,k)=0. ZFLUX_i(i,1,k)=0. ZFLUX_i(i,2,k)=0. ZFLUC_i(i,1,k)=0. ZFLUC_i(i,2,k)=0. ZFSDWN_i(i,k)=0. ZFCDWN_i(i,k)=0. ZFCCDWN_i(i,k)=0. ZFSUP_i(i,k)=0. ZFCUP_i(i,k)=0. ZFCCUP_i(i,k)=0. ZFLCCDWN_i(i,k)=0. ZFLCCUP_i(i,k)=0. ENDDO ENDDO ! ! AI ATTENTION Aerosols A REVOIR DO i = 1, kdlon DO k = 1, kflev DO kk= 1, naero_grp ! DO kk=1, NSW ! ! PTAU_TOT(i,kflev+1-k,kk)=tau_aero_sw_rrtm(i,k,2,kk) ! PPIZA_TOT(i,kflev+1-k,kk)=piz_aero_sw_rrtm(i,k,2,kk) ! PCGA_TOT(i,kflev+1-k,kk)=cg_aero_sw_rrtm(i,k,2,kk) ! ! PTAU_NAT(i,kflev+1-k,kk)=tau_aero_sw_rrtm(i,k,1,kk) ! PPIZA_NAT(i,kflev+1-k,kk)=piz_aero_sw_rrtm(i,k,1,kk) ! PCGA_NAT(i,kflev+1-k,kk)=cg_aero_sw_rrtm(i,k,1,kk) ! ZAEROSOL(i,kflev+1-k,kk)=m_allaer(i,k,kk) ZAEROSOL(i,kflev+1-k,kk)=m_allaer(i,k,kk) ! ENDDO ENDDO ENDDO !-end OB ! ! DO i = 1, kdlon ! DO k = 1, kflev ! DO kk=1, NLW ! ! PTAU_LW_TOT(i,kflev+1-k,kk)=tau_aero_lw_rrtm(i,k,2,kk) ! PTAU_LW_NAT(i,kflev+1-k,kk)=tau_aero_lw_rrtm(i,k,1,kk) ! ! ENDDO ! ENDDO ! ENDDO !-end C. Kleinschmitt ! DO i = 1, kdlon ZCTRSO(i,1)=0. ZCTRSO(i,2)=0. ZCEMTR(i,1)=0. ZCEMTR(i,2)=0. ZTRSOD(i)=0. ZLWFC(i,1)=0. ZLWFC(i,2)=0. ZSWFC(i,1)=0. ZSWFC(i,2)=0. PFSDNN(i)=0. PFSDNV(i)=0. DO kk = 1, NSW PSFSWDIR(i,kk)=0. PSFSWDIF(i,kk)=0. ENDDO ENDDO !----- Fin des mises a zero des tableaux output ------------------- ! On met les donnees dans l'ordre des niveaux ecrad ! print*,'On inverse sur la verticale ' paprs_i(:,1)=paprs(:,klev+1) DO k=1,klev paprs_i(1:klon,k+1) =paprs(1:klon,klev+1-k) pplay_i(1:klon,k) =pplay(1:klon,klev+1-k) cldfra_i(1:klon,k) =cldfra(1:klon,klev+1-k) PDP_i(1:klon,k) =PDP(1:klon,klev+1-k) t_i(1:klon,k) =t(1:klon,klev+1-k) q_i(1:klon,k) =q(1:klon,klev+1-k) qsat_i(1:klon,k) =qsat(1:klon,klev+1-k) flwc_i(1:klon,k) =flwc(1:klon,klev+1-k) fiwc_i(1:klon,k) =fiwc(1:klon,klev+1-k) ref_liq_i(1:klon,k) =ref_liq(1:klon,klev+1-k)*1.0e-6 ref_ice_i(1:klon,k) =ref_ice(1:klon,klev+1-k)*1.0e-6 !-OB ref_liq_pi_i(1:klon,k) =ref_liq_pi(1:klon,klev+1-k) ref_ice_pi_i(1:klon,k) =ref_ice_pi(1:klon,klev+1-k) ENDDO DO k=1,kflev POZON_i(1:klon,k,:)=POZON(1:klon,kflev+1-k,:) ! ZO3_DP_i(1:klon,k)=ZO3_DP(1:klon,kflev+1-k) ! DO i=1,6 PAER_i(1:klon,k,:)=PAER(1:klon,kflev+1-k,:) ! ENDDO ENDDO ! AI 11.2021 ! Calcul de ZTH_i (temp aux interfaces 1:klev+1) ! 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: ! AI ATTENTION fais dans interface radlw !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)) DO K=2,KLEV DO i = 1, kdlon ZTH_i(i,K)=& & (t_i(i,K-1)*pplay_i(i,K-1)*(pplay_i(i,K)-paprs_i(i,K))& & +t_i(i,K)*pplay_i(i,K)*(paprs_i(i,K)-pplay_i(i,K-1)))& & *(1.0/(paprs_i(i,K)*(pplay_i(i,K)-pplay_i(i,K-1)))) ENDDO ENDDO DO i = 1, kdlon ! Sommet ZTH_i(i,1)=t_i(i,1)-pplay_i(i,1)*(t_i(i,1)-ZTH_i(i,2))& & /(pplay_i(i,1)-paprs_i(i,2)) ! Vers le sol ZTH_i(i,KLEV+1)=t_i(i,KLEV) + 0.5 * & (tsol(i) - ZTH_i(i,KLEV)) ENDDO print *,'RADLWSW: avant RADIATION_SCHEME ' ! AI mars 2022 SOLARIRAD = solaire/zdist/zdist !! diagnos pour la comparaison a la version offline !!! - Gas en VMR pour offline et MMR pour online !!! - on utilise pour solarirrad une valeur constante if (lldebug_for_offline) then SOLARIRAD = 1366.0896 ZCH4_off = CH4_ppb*1e-9 ZN2O_off = N2O_ppb*1e-9 ZNO2_off = 0.0 ZCFC11_off = CFC11_ppt*1e-12 ZCFC12_off = CFC12_ppt*1e-12 ZHCFC22_off = 0.0 ZCCL4_off = 0.0 ZO2_off = 0.0 ZCO2_off = co2_ppm*1e-6 CALL writefield_phy('rmu0',rmu0,1) CALL writefield_phy('tsol',tsol,1) CALL writefield_phy('emissiv_out',ZEMIS,1) CALL writefield_phy('paprs_i',paprs_i,klev+1) CALL writefield_phy('ZTH_i',ZTH_i,klev+1) CALL writefield_phy('cldfra_i',cldfra_i,klev) CALL writefield_phy('q_i',q_i,klev) CALL writefield_phy('fiwc_i',fiwc_i,klev) CALL writefield_phy('flwc_i',flwc_i,klev) CALL writefield_phy('palbd_new',PALBD_NEW,NSW) CALL writefield_phy('palbp_new',PALBP_NEW,NSW) CALL writefield_phy('POZON',POZON_i(:,:,1),klev) CALL writefield_phy('ZCO2',ZCO2_off,klev) CALL writefield_phy('ZCH4',ZCH4_off,klev) CALL writefield_phy('ZN2O',ZN2O_off,klev) CALL writefield_phy('ZO2',ZO2_off,klev) CALL writefield_phy('ZNO2',ZNO2_off,klev) CALL writefield_phy('ZCFC11',ZCFC11_off,klev) CALL writefield_phy('ZCFC12',ZCFC12_off,klev) CALL writefield_phy('ZHCFC22',ZHCFC22_off,klev) CALL writefield_phy('ZCCL4',ZCCL4_off,klev) CALL writefield_phy('ref_liq_i',ref_liq_i,klev) CALL writefield_phy('ref_ice_i',ref_ice_i,klev) endif ! lldebug_for_offline CALL RADIATION_SCHEME & & (ist, iend, klon, klev, naero_grp, NSW, & & day_cur, current_time, & ! Cste solaire/(d_Terre-Soleil)**2 & SOLARIRAD, & ! Cos(angle zin), temp sol & rmu0, tsol, & ! Albedo diffuse et directe & PALBD_NEW,PALBP_NEW, & ! Emessivite : PEMIS_WINDOW (???), & & ZEMIS, ZEMISW, & ! longitude(rad), sin(latitude), PMASQ_ ??? & ZGELAM, ZGEMU, & ! Temp et pres aux interf, vapeur eau, Satur spec humid & paprs_i, ZTH_i, q_i, qsat_i, & ! Gas & ZCO2, ZCH4, ZN2O, ZNO2, ZCFC11, ZCFC12, ZHCFC22, & & ZCCL4, POZON_i(:,:,1), ZO2, & ! nuages : & cldfra_i, flwc_i, fiwc_i, ZQ_SNOW, & ! rayons effectifs des gouttelettes & ref_liq_i, ref_ice_i, & ! aerosols & ZAEROSOL_OLD, ZAEROSOL, & ! Outputs ! Net flux : & ZSWFT_i, ZLWFT_i, ZSWFT0_ii, ZLWFT0_ii, & ! DWN flux : & ZFSDWN_i, ZFLUX_i(:,2,:), ZFCDWN_i, ZFLUC_i(:,2,:), & ! UP flux : & ZFSUP_i, ZFLUX_i(:,1,:), ZFCUP_i, ZFLUC_i(:,1,:), & ! Surf Direct flux : ATTENTION & ZFLUX_DIR, ZFLUX_DIR_CLEAR, ZFLUX_DIR_INTO_SUN, & ! UV and para flux & ZFLUX_UV, ZFLUX_PAR, ZFLUX_PAR_CLEAR, & ! & ZFLUX_SW_DN_TOA, & ZEMIS_OUT, ZLWDERIVATIVE, & & PSFSWDIF, PSFSWDIR) print *,'========= RADLWSW: apres RADIATION_SCHEME ==================== ' if (lldebug_for_offline) then CALL writefield_phy('FLUX_LW',ZLWFT_i,klev+1) CALL writefield_phy('FLUX_LW_CLEAR',ZLWFT0_ii,klev+1) CALL writefield_phy('FLUX_SW',ZSWFT_i,klev+1) CALL writefield_phy('FLUX_SW_CLEAR',ZSWFT0_ii,klev+1) CALL writefield_phy('FLUX_DN_SW',ZFSDWN_i,klev+1) CALL writefield_phy('FLUX_DN_LW',ZFLUX_i(:,2,:),klev+1) CALL writefield_phy('FLUX_DN_SW_CLEAR',ZFCDWN_i,klev+1) CALL writefield_phy('FLUX_DN_LW_CLEAR',ZFLUC_i(:,2,:),klev+1) CALL writefield_phy('PSFSWDIR',PSFSWDIR,6) CALL writefield_phy('PSFSWDIF',PSFSWDIF,6) CALL writefield_phy('FLUX_UP_LW',ZFLUX_i(:,1,:),klev+1) CALL writefield_phy('FLUX_UP_LW_CLEAR',ZFLUC_i(:,1,:),klev+1) CALL writefield_phy('FLUX_UP_SW',ZFSUP_i,klev+1) CALL writefield_phy('FLUX_UP_SW_CLEAR',ZFCUP_i,klev+1) endif ! --------- ! On retablit l'ordre des niveaux lmd pour les tableaux de sortie ! D autre part, on multiplie les resultats SW par fract pour etre coherent ! avec l ancien rayonnement AR4. Si nuit, fract=0 donc pas de ! rayonnement SW. (MPL 260609) print*,'On retablit l ordre des niveaux verticaux pour LMDZ' print*,'On multiplie les flux SW par fract et LW dwn par -1' DO k=0,klev DO i=1,klon ZEMTD(i,k+1) = ZEMTD_i(i,klev+1-k) ZEMTU(i,k+1) = ZEMTU_i(i,klev+1-k) ZTRSO(i,k+1) = ZTRSO_i(i,klev+1-k) ! ZTH(i,k+1) = ZTH_i(i,klev+1-k) ! AI ATTENTION ZLWFT(i,k+1) = ZLWFT_i(i,klev+1-k) ZSWFT(i,k+1) = ZSWFT_i(i,klev+1-k)*fract(i) ZSWFT0_i(i,k+1) = ZSWFT0_ii(i,klev+1-k)*fract(i) ZLWFT0_i(i,k+1) = ZLWFT0_ii(i,klev+1-k) ! ZFLUP(i,k+1) = ZFLUX_i(i,1,klev+1-k) ZFLDN(i,k+1) = -1.*ZFLUX_i(i,2,klev+1-k) ZFLUP0(i,k+1) = ZFLUC_i(i,1,klev+1-k) ZFLDN0(i,k+1) = -1.*ZFLUC_i(i,2,klev+1-k) ZFSDN(i,k+1) = ZFSDWN_i(i,klev+1-k)*fract(i) ZFSDN0(i,k+1) = ZFCDWN_i(i,klev+1-k)*fract(i) ZFSDNC0(i,k+1)= ZFCCDWN_i(i,klev+1-k)*fract(i) ZFSUP (i,k+1) = ZFSUP_i(i,klev+1-k)*fract(i) ZFSUP0(i,k+1) = ZFCUP_i(i,klev+1-k)*fract(i) ZFSUPC0(i,k+1)= ZFCCUP_i(i,klev+1-k)*fract(i) ZFLDNC0(i,k+1)= -1.*ZFLCCDWN_i(i,klev+1-k) ZFLUPC0(i,k+1)= ZFLCCUP_i(i,klev+1-k) IF (ok_volcan) THEN ZSWADAERO(i,k+1)=ZSWADAERO(i,klev+1-k)*fract(i) !--NL ENDIF ! Nouveau calcul car visiblement ZSWFT et ZSWFC sont nuls dans RRTM cy32 ! en sortie de radlsw.F90 - MPL 7.01.09 ! AI ATTENTION ! ZSWFT(i,k+1) = (ZFSDWN_i(i,k+1)-ZFSUP_i(i,k+1))*fract(i) ! ZSWFT0_i(i,k+1) = (ZFCDWN_i(i,k+1)-ZFCUP_i(i,k+1))*fract(i) ! ZLWFT(i,k+1) =-ZFLUX_i(i,2,k+1)-ZFLUX_i(i,1,k+1) ! ZLWFT0_i(i,k+1)=-ZFLUC_i(i,2,k+1)-ZFLUC_i(i,1,k+1) ENDDO ENDDO !--ajout OB ZTOPSWADAERO(:) =ZTOPSWADAERO(:) *fract(:) ZSOLSWADAERO(:) =ZSOLSWADAERO(:) *fract(:) ZTOPSWAD0AERO(:)=ZTOPSWAD0AERO(:)*fract(:) ZSOLSWAD0AERO(:)=ZSOLSWAD0AERO(:)*fract(:) ZTOPSWAIAERO(:) =ZTOPSWAIAERO(:) *fract(:) ZSOLSWAIAERO(:) =ZSOLSWAIAERO(:) *fract(:) ZTOPSWCF_AERO(:,1)=ZTOPSWCF_AERO(:,1)*fract(:) ZTOPSWCF_AERO(:,2)=ZTOPSWCF_AERO(:,2)*fract(:) ZTOPSWCF_AERO(:,3)=ZTOPSWCF_AERO(:,3)*fract(:) ZSOLSWCF_AERO(:,1)=ZSOLSWCF_AERO(:,1)*fract(:) ZSOLSWCF_AERO(:,2)=ZSOLSWCF_AERO(:,2)*fract(:) ZSOLSWCF_AERO(:,3)=ZSOLSWCF_AERO(:,3)*fract(:) ! --------- ! On renseigne les champs LMDz, pour avoir la meme chose qu'en sortie de ! LW_LMDAR4 et SW_LMDAR4 !--fraction of diffuse radiation in surface SW downward radiation DO i = 1, kdlon zdir=SUM(PSFSWDIR(i,:)) zdif=SUM(PSFSWDIF(i,:)) IF (fract(i).GT.0.0.and.(zdir+zdif).gt.seuilmach) THEN zsolswfdiff(i) = zdif/(zdir+zdif) ELSE !--night zsolswfdiff(i) = 1.0 ENDIF ENDDO ! DO i = 1, kdlon zsolsw(i) = ZSWFT(i,1) zsolsw0(i) = ZSWFT0_i(i,1) ztopsw(i) = ZSWFT(i,klev+1) ztopsw0(i) = ZSWFT0_i(i,klev+1) zsollw(i) = ZLWFT(i,1) zsollw0(i) = ZLWFT0_i(i,1) ztoplw(i) = ZLWFT(i,klev+1)*(-1) ztoplw0(i) = ZLWFT0_i(i,klev+1)*(-1) ! zsollwdown(i)= -1.*ZFLDN(i,1) ENDDO DO k=1,kflev DO i=1,kdlon zheat(i,k)=(ZSWFT(i,k+1)-ZSWFT(i,k))*RDAY*RG/RCPD/PDP(i,k) zheat0(i,k)=(ZSWFT0_i(i,k+1)-ZSWFT0_i(i,k))*RDAY*RG/RCPD/PDP(i,k) zcool(i,k)=(ZLWFT(i,k)-ZLWFT(i,k+1))*RDAY*RG/RCPD/PDP(i,k) zcool0(i,k)=(ZLWFT0_i(i,k)-ZLWFT0_i(i,k+1))*RDAY*RG/RCPD/PDP(i,k) IF (ok_volcan) THEN zheat_volc(i,k)=(ZSWADAERO(i,k+1)-ZSWADAERO(i,k))*RG/RCPD/PDP(i,k) !NL zcool_volc(i,k)=(ZLWADAERO(i,k)-ZLWADAERO(i,k+1))*RG/RCPD/PDP(i,k) !NL ENDIF ENDDO ENDDO #endif print*,'Fin traitement ECRAD' ! Fin ECRAD ENDIF ! iflag_rrtm ! ecrad !====================================================================== DO i = 1, kdlon topsw(iof+i) = ztopsw(i) toplw(iof+i) = ztoplw(i) solsw(iof+i) = zsolsw(i) solswfdiff(iof+i) = zsolswfdiff(i) sollw(iof+i) = zsollw(i) sollwdown(iof+i) = zsollwdown(i) DO k = 1, kflev+1 lwdn0 ( iof+i,k) = ZFLDN0 ( i,k) lwdn ( iof+i,k) = ZFLDN ( i,k) lwup0 ( iof+i,k) = ZFLUP0 ( i,k) lwup ( iof+i,k) = ZFLUP ( i,k) ENDDO topsw0(iof+i) = ztopsw0(i) toplw0(iof+i) = ztoplw0(i) solsw0(iof+i) = zsolsw0(i) sollw0(iof+i) = zsollw0(i) albpla(iof+i) = zalbpla(i) DO k = 1, kflev+1 swdnc0( iof+i,k) = ZFSDNC0( i,k) swdn0 ( iof+i,k) = ZFSDN0 ( i,k) swdn ( iof+i,k) = ZFSDN ( i,k) swupc0( iof+i,k) = ZFSUPC0( i,k) swup0 ( iof+i,k) = ZFSUP0 ( i,k) swup ( iof+i,k) = ZFSUP ( i,k) lwdnc0( iof+i,k) = ZFLDNC0( i,k) lwupc0( iof+i,k) = ZFLUPC0( i,k) ENDDO ENDDO !-transform the aerosol forcings, if they have ! to be calculated IF (ok_ade) THEN DO i = 1, kdlon topswad_aero(iof+i) = ztopswadaero(i) topswad0_aero(iof+i) = ztopswad0aero(i) solswad_aero(iof+i) = zsolswadaero(i) solswad0_aero(iof+i) = zsolswad0aero(i) topsw_aero(iof+i,:) = ztopsw_aero(i,:) topsw0_aero(iof+i,:) = ztopsw0_aero(i,:) solsw_aero(iof+i,:) = zsolsw_aero(i,:) solsw0_aero(iof+i,:) = zsolsw0_aero(i,:) topswcf_aero(iof+i,:) = ztopswcf_aero(i,:) solswcf_aero(iof+i,:) = zsolswcf_aero(i,:) !-LW toplwad_aero(iof+i) = ztoplwadaero(i) toplwad0_aero(iof+i) = ztoplwad0aero(i) sollwad_aero(iof+i) = zsollwadaero(i) sollwad0_aero(iof+i) = zsollwad0aero(i) ENDDO ELSE DO i = 1, kdlon topswad_aero(iof+i) = 0.0 solswad_aero(iof+i) = 0.0 topswad0_aero(iof+i) = 0.0 solswad0_aero(iof+i) = 0.0 topsw_aero(iof+i,:) = 0. topsw0_aero(iof+i,:) =0. solsw_aero(iof+i,:) = 0. solsw0_aero(iof+i,:) = 0. !-LW toplwad_aero(iof+i) = 0.0 sollwad_aero(iof+i) = 0.0 toplwad0_aero(iof+i) = 0.0 sollwad0_aero(iof+i) = 0.0 ENDDO ENDIF IF (ok_aie) THEN DO i = 1, kdlon topswai_aero(iof+i) = ztopswaiaero(i) solswai_aero(iof+i) = zsolswaiaero(i) !-LW toplwai_aero(iof+i) = ztoplwaiaero(i) sollwai_aero(iof+i) = zsollwaiaero(i) ENDDO ELSE DO i = 1, kdlon topswai_aero(iof+i) = 0.0 solswai_aero(iof+i) = 0.0 !-LW toplwai_aero(iof+i) = 0.0 sollwai_aero(iof+i) = 0.0 ENDDO ENDIF DO k = 1, kflev DO i = 1, kdlon ! scale factor to take into account the difference between ! dry air and watter vapour scpecifi! heat capacity zznormcp=1.0+RVTMP2*PWV(i,k) heat(iof+i,k) = zheat(i,k)/zznormcp cool(iof+i,k) = zcool(i,k)/zznormcp heat0(iof+i,k) = zheat0(i,k)/zznormcp cool0(iof+i,k) = zcool0(i,k)/zznormcp IF(ok_volcan) THEN !NL heat_volc(iof+i,k) = zheat_volc(i,k)/zznormcp cool_volc(iof+i,k) = zcool_volc(i,k)/zznormcp ENDIF ENDDO ENDDO ENDDO ! j = 1, nb_gr IF (lldebug) THEN if (0.eq.1) then ! Verifs dans le cas 1D print*,'================== Sortie de radlw =================' print*,'******** LW LW LW *******************' print*,'ZLWFT =',ZLWFT print*,'ZLWFT0_i =',ZLWFT0_i print*,'ZFLUP0 =',ZFLUP0 print*,'ZFLDN0 =',ZFLDN0 print*,'ZFLDNC0 =',ZFLDNC0 print*,'ZFLUPC0 =',ZFLUPC0 print*,'******** SW SW SW *******************' print*,'ZSWFT =',ZSWFT print*,'ZSWFT0_i =',ZSWFT0_i print*,'ZFSDN =',ZFSDN print*,'ZFSDN0 =',ZFSDN0 print*,'ZFSDNC0 =',ZFSDNC0 print*,'ZFSUP =',ZFSUP print*,'ZFSUP0 =',ZFSUP0 print*,'ZFSUPC0 =',ZFSUPC0 print*,'******** LMDZ *******************' print*,'cool = ', cool print*,'heat = ', heat print*,'topsw = ', topsw print*,'toplw = ', toplw print*,'sollw = ', sollw print*,'solsw = ', solsw print*,'lwdn = ', lwdn print*,'lwup = ', lwup print*,'swdn = ', swdn print*,'swup =', swup endif ENDIF END SUBROUTINE radlwsw end module radlwsw_m