SUBROUTINE RADLSW & & ( KIDIA, KFDIA , KLON , KLEV , KMODE, KAER,& & PRII0,& & PAER , PALBD , PALBP, PAPH , PAP,& & PCCNL, PCCNO,& & PCCO2, PCLFR , PDP , PEMIS, PEMIW , PLSM , PMU0, POZON,& & PQ , PQIWP , PQLWP, PQS , PQRAIN, PRAINT,& & PTH , PT , PTS , PNBAS, PNTOP,& & PREF_LIQ, PREF_ICE,& & PEMIT, PFCT , PFLT , PFCS , PFLS,& & PFRSOD,PSUDU , PUVDF, PPARF, PPARCF, PTINCF,& & PSFSWDIR, PSFSWDIF,PFSDNN,PFSDNV ,& & LRDUST,PPIZA_DST,PCGA_DST,PTAUREL_DST,& & PTAU_LW,& & PFLUX,PFLUC,PFSDN ,PFSUP , PFSCDN , PFSCUP) USE lmdz_writefield_phy, ONLY: writefield_phy !**** *RADLSW* - INTERFACE TO ECMWF LW AND SW RADIATION SCHEMES ! PURPOSE. ! -------- ! CONTROLS RADIATION COMPUTATIONS !** INTERFACE. ! ---------- ! EXPLICIT ARGUMENTS : ! -------------------- ! PAER : (KLON,6,KLEV) ; OPTICAL THICKNESS OF THE AEROSOLS ! PALBD : (KLON,NSW) ; SURF. SW ALBEDO FOR DIFFUSE RADIATION ! PALBP : (KLON,NSW) ; SURF. SW ALBEDO FOR PARALLEL RADIATION ! PAPH : (KLON,KLEV+1) ; HALF LEVEL PRESSURE ! PAP : (KLON,KLEV) ; FULL LEVEL PRESSURE ! PCCNL : (KLON) ; CCN CONCENTRATION OVER LAND ! PCCNO : (KLON) ; CCN CONCENTRATION OVER OCEAN ! PCCO2 : ; CONCENTRATION IN CO2 (KG/KG) ! PCLFR : (KLON,KLEV) ; CLOUD FRACTIONAL COVER ! PDP : (KLON,KLEV) ; LAYER PRESSURE THICKNESS ! PEMIS : (KLON) ; SURFACE LW EMISSIVITY ! PEMIW : (KLON) ; SURFACE LW WINDOW EMISSIVITY ! PLSM : (KLON) ; LAND-SEA MASK ! PMU0 : (KLON) ; SOLAR ANGLE ! PNBAS : (KLON) ; INDEX OF BASE OF CONVECTIVE LAYER ! PNTOP : (KLON) ; INDEX OF TOP OF CONVECTIVE LAYER ! POZON : (KLON,KLEV) ; OZONE AMOUNT in LAYER (KG/KG*PA) ! PQ : (KLON,KLEV) ; SPECIFIC HUMIDITY KG/KG ! PQIWP : (KLON,KLEV) ; SOLID WATER KG/KG ! PQLWP : (KLON,KLEV) ; LIQUID WATER KG/KG ! PQS : (KLON,KLEV) ; SATURATION WATER VAPOR KG/KG ! PQRAIN : (KLON,KLEV) ; RAIN WATER KG/KG ! PRAINT : (KLON,KLEV) ; RAIN RATE (m/s) ! PTH : (KLON,KLEV+1) ; HALF LEVEL TEMPERATURE ! PT : (KLON,KLEV) ; FULL LEVEL TEMPERATURE ! PTS : (KLON) ; SURFACE TEMPERATURE ! LDDUST ; Dust properties switch ! PPIZA_DST : (KPROMA,KLEV,NSW); Single scattering albedo of dust ! PCGA_DST : (KPROMA,KLEV,NSW); Assymetry factor for dust ! PTAUREL_DST: (KPROMA,KLEV,NSW); Optical depth of dust relative to at 550nm ! PTAU_LW (KPROMA,KLEV,NLW); LW Optical depth of aerosols ! PREF_LIQ (KPROMA,KLEV) ; Liquid droplet radius (um) ! PREF_ICE (KPROMA,KLEV) ; Ice crystal radius (um) ! ==== OUTPUTS === ! PFCT : (KLON,KLEV+1) ; CLEAR-SKY LW NET FLUXES ! PFLT : (KLON,KLEV+1) ; TOTAL LW NET FLUXES ! PFCS : (KLON,KLEV+1) ; CLEAR-SKY SW NET FLUXES ! PFLS : (KLON,KLEV+1) ; TOTAL SW NET FLUXES ! PFRSOD : (KLON) ; TOTAL-SKY SURFACE SW DOWNWARD FLUX ! PEMIT : (KLON) ; SURFACE TOTAL LONGWAVE EMISSIVITY ! PSUDU : (KLON) ; SOLAR RADIANCE IN SUN'S DIRECTION ! PPARF : (KLON) ; PHOTOSYNTHETICALLY ACTIVE RADIATION ! PUVDF : (KLON) ; UV(-B) RADIATION ! PPARCF : (KLON) ; CLEAR-SKY PHOTOSYNTHETICALLY ACTIVE RADIATION ! PTINCF : (KLON) ; TOA INCIDENT SOLAR RADIATION ! Ajout flux LW et SW montants et descendants, et ciel clair (MPL 19.12.08) ! PFLUX : (KLON,2,KLEV+1) ; LW total sky flux (1=up, 2=down) ! PFLUC : (KLON,2,KLEV+1) ; LW clear sky flux (1=up, 2=down) ! PFSDN(KLON,KLEV+1) ; SW total sky flux down ! PFSUP(KLON,KLEV+1) ; SW total sky flux up ! PFSCDN(KLON,KLEV+1) ; SW clear sky flux down ! PFSCUP(KLON,KLEV+1) ; SW clear sky flux up ! IMPLICIT ARGUMENTS : NONE ! -------------------- ! METHOD. ! ------- ! SEE DOCUMENTATION ! EXTERNALS. ! ---------- ! REFERENCE. ! ---------- ! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS ! AUTHORS. ! -------- ! J.-J. MORCRETTE *ECMWF* ! MODIFICATIONS. ! -------------- ! ORIGINAL : 88-02-04 ! J.-J. MORCRETTE 94-11-15 DIRECT/DIFFUSE SURFACE ALBEDO ! 08/96: J.-J. Morcrette/Ph. Dandin: tests of eff. radius param. ! 9909 : JJMorcrette effect.radius + inhomogeneity factors ! JJMorcrette 990128 : sunshine duration ! JJMorcrette : 990831 RRTM-140gp ! JJMorcrette : 010112 Sun-Rikus ice particle Diameter ! JJMorcrette : 010301 cleaning liq/ice cloud optical properties ! JJMorcrette : 011005 CCN --> Re liquid water clouds ! JJMorcrette : 011108 Safety checks ! JJMorcrette : 011108 Safety checks ! DJSalmond : 020211 Check before R-To-R ! JJMorcrette : 020901 PAR & UV ! M.Hamrud 01-Oct-2003 CY28 Cleaning ! JJMorcrette : 050402 New sets of optical properties (NB: inactive) ! Y.Seity 04-11-18 : add 4 arguments for AROME externalized surface ! Y.Seity 05-10-10 : add 3 optional arg. for dust SW properties ! JJMorcrette 20060721 PP of clear-sky PAR and TOA incident solar radiation !----------------------------------------------------------------------- USE PARKIND1 ,ONLY : JPIM ,JPRB USE YOMHOOK ,ONLY : LHOOK, DR_HOOK USE YOMCST , ONLY : RG ,RD ,RTT ,RPI !USE YOERAD , ONLY : NSW ,LRRTM ,LCCNL ,LCCNO, LDIFFC, & ! NSW mis dans .def MPL 20140211 USE YOERAD , ONLY : NLW, LRRTM ,LCCNL ,LCCNO, LDIFFC, & & NRADIP , NRADLP , NICEOPT, NLIQOPT, NINHOM ,NLAYINH ,& & RCCNLND, RCCNSEA, RLWINHF, RSWINHF, RRe2De ,& & LEDBUG 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 ,RFUETB ,RFUETC ,RASWCA ,& & RASWCB ,RASWCC ,RASWCD ,RASWCE ,RASWCF ,& & RFUAA0 ,RFUAA1 ,RFUBB0 ,RFUBB1 ,RFUBB2 ,& & RFUBB3 ,RFUCC0 ,RFUCC1 ,RFUCC2 ,RFUCC3 ,& & RLILIA ,RLILIB USE YOERDU , ONLY : NUAER ,NTRAER ,REPLOG ,REPSC ,REPSCW ,DIFF !USE YOETHF , ONLY : RTICE USE YOEPHLI , ONLY : LPHYLIN USE YOERRTWN , ONLY : DELWAVE ,TOTPLNK USE YOMLUN_IFSAUX , ONLY : NULOUT USE YOMCT3 , ONLY : NSTEP USE lmdz_clesphys USE lmdz_yoethf IMPLICIT NONE !!include "clesrrtm.h" INTEGER(KIND=JPIM),INTENT(IN) :: KLON INTEGER(KIND=JPIM),INTENT(IN) :: KLEV INTEGER(KIND=JPIM),INTENT(IN) :: KIDIA INTEGER(KIND=JPIM),INTENT(IN) :: KFDIA INTEGER(KIND=JPIM),INTENT(IN) :: KMODE INTEGER(KIND=JPIM),INTENT(IN) :: KAER REAL(KIND=JPRB) ,INTENT(IN) :: PRII0 REAL(KIND=JPRB) ,INTENT(IN) :: PAER(KLON,6,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PALBD(KLON,NSW) REAL(KIND=JPRB) ,INTENT(IN) :: PALBP(KLON,NSW) REAL(KIND=JPRB) ,INTENT(IN) :: PAPH(KLON,KLEV+1) REAL(KIND=JPRB) ,INTENT(IN) :: PAP(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PCCNL(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PCCNO(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PCCO2 REAL(KIND=JPRB) ,INTENT(IN) :: PCLFR(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PDP(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PEMIS(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PEMIW(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PLSM(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PMU0(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: POZON(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PQ(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PQIWP(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PQLWP(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PQS(KLON,KLEV) REAL(KIND=JPRB) :: PQRAIN(KLON,KLEV) ! Argument NOT used REAL(KIND=JPRB) :: PRAINT(KLON,KLEV) ! Argument NOT used REAL(KIND=JPRB) ,INTENT(IN) :: PTH(KLON,KLEV+1) REAL(KIND=JPRB) ,INTENT(IN) :: PT(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PTS(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PNBAS(KLON) REAL(KIND=JPRB) ,INTENT(IN) :: PNTOP(KLON) LOGICAL ,INTENT(IN) :: LRDUST REAL(KIND=JPRB) ,INTENT(IN) :: PPIZA_DST(KLON,KLEV,NSW) REAL(KIND=JPRB) ,INTENT(IN) :: PCGA_DST(KLON,KLEV,NSW) REAL(KIND=JPRB) ,INTENT(IN) :: PTAUREL_DST(KLON,KLEV,NSW) !--C.Kleinschmitt REAL(KIND=JPRB) ,INTENT(IN) :: PTAU_LW(KLON,KLEV,NLW) !--end REAL(KIND=JPRB) ,INTENT(IN) :: PREF_LIQ(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(IN) :: PREF_ICE(KLON,KLEV) REAL(KIND=JPRB) ,INTENT(OUT) :: PEMIT(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PFCT(KLON,KLEV+1) REAL(KIND=JPRB) ,INTENT(OUT) :: PFLT(KLON,KLEV+1) REAL(KIND=JPRB) ,INTENT(OUT) :: PFCS(KLON,KLEV+1) REAL(KIND=JPRB) ,INTENT(OUT) :: PFLS(KLON,KLEV+1) REAL(KIND=JPRB) ,INTENT(OUT) :: PFRSOD(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PSUDU(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PUVDF(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PPARF(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PPARCF(KLON), PTINCF(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PSFSWDIR(KLON,NSW) REAL(KIND=JPRB) ,INTENT(OUT) :: PSFSWDIF(KLON,NSW) REAL(KIND=JPRB) ,INTENT(OUT) :: PFSDNN(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PFSDNV(KLON) REAL(KIND=JPRB) ,INTENT(OUT) :: PFLUX(KLON,2,KLEV+1) ! LW total sky flux (1=up, 2=down) REAL(KIND=JPRB) ,INTENT(OUT) :: PFLUC(KLON,2,KLEV+1) ! LW clear sky flux (1=up, 2=down) REAL(KIND=JPRB) ,INTENT(OUT) :: PFSDN(KLON,KLEV+1) ! SW total sky flux down REAL(KIND=JPRB) ,INTENT(OUT) :: PFSUP(KLON,KLEV+1) ! SW total sky flux up REAL(KIND=JPRB) ,INTENT(OUT) :: PFSCDN(KLON,KLEV+1) ! SW clear sky flux down REAL(KIND=JPRB) ,INTENT(OUT) :: PFSCUP(KLON,KLEV+1) ! SW clear sky flux up ! ----------------------------------------------------------------- !* 0.1 ARGUMENTS. ! ---------- ! ==== COMPUTED IN RADLSW === ! ----------------------------------------------------------------- !* 0.2 LOCAL ARRAYS. ! ------------- ! ----------------------------------------------------------------- !-- ARRAYS FOR LOCAL VARIABLES ----------------------------------------- INTEGER(KIND=JPIM) :: IBAS(KLON) , ITOP(KLON) REAL(KIND=JPRB) ::& & ZALBD(KLON,NSW) , ZALBP(KLON,NSW)& & , ZCG(KLON,NSW,KLEV) , ZOMEGA(KLON,NSW,KLEV)& & , ZTAU (KLON,NSW,KLEV) & & , ZTAUCLD(KLON,KLEV,16), ZTCLEAR(KLON) REAL(KIND=JPRB) ::& & ZCLDLD(KLON,KLEV) , ZCLDLU(KLON,KLEV)& & , ZCLDSW(KLON,KLEV) , ZCLD0(KLON,KLEV)& & , ZDT0(KLON) & & , ZEMIS(KLON) , ZEMIW(KLON)& & , ZFIWP(KLON) , ZFLWP(KLON) , ZFRWP(KLON)& & , ZIWC(KLON) , ZLWC(KLON)& !cc , ZRWC(KLON) & , ZMU0(KLON) , ZOZ(KLON,KLEV) , ZOZN(KLON,KLEV)& & , ZPMB(KLON,KLEV+1) , ZPSOL(KLON)& & , ZTAVE (KLON,KLEV) , ZTL(KLON,KLEV+1)& & , ZVIEW(KLON) REAL(KIND=JPRB) ::& & ZFCDWN(KLON,KLEV+1), ZFCUP(KLON,KLEV+1)& & , ZFSDWN(KLON,KLEV+1), ZFSUP(KLON,KLEV+1)& & , ZFSUPN(KLON) , ZFSUPV(KLON)& & , ZFCUPN(KLON) , ZFCUPV(KLON)& & , ZFSDNN(KLON) , ZFSDNV(KLON)& & , ZFCDNN(KLON) , ZFCDNV(KLON)& & , ZDIRFS(KLON,NSW) , ZDIFFS(KLON,NSW) REAL(KIND=JPRB) ::& & ZALFICE(KLON) , ZGAMICE(KLON) , ZBICE(KLON) , ZDESR(KLON)& & , ZRADIP(KLON) , ZRADLP(KLON) & !cc , ZRADRD(KLON) & , ZRAINT(KLON) , ZRES(KLON)& & , ZTICE(KLON) , ZEMIT(KLON), ZBICFU(KLON)& & , ZKICFU(KLON) REAL(KIND=JPRB) :: ZSUDU(KLON) , ZPARF(KLON) , ZUVDF(KLON), ZPARCF(KLON) INTEGER(KIND=JPIM) :: IKL, JK, JKL, JKLP1, JKP1, JL, JNU, JRTM, JSW, INDLAY REAL(KIND=JPRB) :: ZASYMX, ZDIFFD, ZGI, ZGL, ZGR, ZIWGKG, ZLWGKG,& & ZMSAID, ZMSAIU, ZMSALD, ZMSALU, ZRSAIA, ZRSAID, ZRSAIE, ZRSAIF, ZRSAIG, ZRSALD, & & ZMULTI, ZMULTL, ZOI , ZOL, & & ZOMGMX, ZOR, ZRMUZ, ZRWGKG, ZTAUD, ZTAUMX, ZTEMPC, & & ZTOI, ZTOL, ZTOR, ZZFIWP, ZZFLWP, ZDPOG, ZPODT REAL(KIND=JPRB) :: ZALND, ZASEA, ZD, ZDEN, ZNTOT, ZNUM, ZRATIO, Z1RADI, & & Z1RADL, ZBETAI, ZOMGI, ZOMGP, ZFDEL, ZTCELS, ZFSR, ZAIWC, & & ZBIWC, ZTBLAY, ZADDPLK, ZPLANCK, ZEXTCF, Z1MOMG, & & ZDefRe, ZRefDe, ZVI , ZMABSD !REAL(KIND=JPRB) :: ZAVDP(KLON), ZAVTO(KLON), ZSQTO(KLON) REAL(KIND=JPRB) :: ZAVTO(KLON), ZSQTO(KLON) REAL(KIND=JPRB) :: ZSQUAR(KLON,KLEV), ZVARIA(KLON,KLEV) INTEGER(KIND=JPIM) :: IKI, JKI, JEXPLR, JXPLDN LOGICAL :: LLDEBUG REAL(KIND=JPRB) :: ZHOOK_HANDLE #include "lw.intfb.h" #include "rrtm_rrtm_140gp.intfb.h" #include "sw.intfb.h" ! ----------------------------------------------------------------- !* 1. SET-UP INPUT QUANTITIES FOR RADIATION ! ------------------------------------- IF (LHOOK) CALL DR_HOOK('RADLSW',0,ZHOOK_HANDLE) LLDEBUG=.FALSE. ZRefDe = RRe2De ZDefRe = 1.0_JPRB / ZRefDe DO JL = KIDIA,KFDIA ZFCUP(JL,KLEV+1) = 0.0_JPRB ZFCDWN(JL,KLEV+1) = REPLOG ZFSUP(JL,KLEV+1) = 0.0_JPRB ZFSDWN(JL,KLEV+1) = REPLOG PFLUX(JL,1,KLEV+1) = 0.0_JPRB PFLUX(JL,2,KLEV+1) = 0.0_JPRB PFLUC(JL,1,KLEV+1) = 0.0_JPRB PFLUC(JL,2,KLEV+1) = 0.0_JPRB ZFSDNN(JL) = 0.0_JPRB ZFSDNV(JL) = 0.0_JPRB ZFCDNN(JL) = 0.0_JPRB ZFCDNV(JL) = 0.0_JPRB ZFSUPN(JL) = 0.0_JPRB ZFSUPV(JL) = 0.0_JPRB ZFCUPN(JL) = 0.0_JPRB ZFCUPV(JL) = 0.0_JPRB ZPSOL(JL) = PAPH(JL,KLEV+1) ZPMB(JL,1) = ZPSOL(JL) / 100.0_JPRB ZDT0(JL) = PTS(JL) - PTH(JL,KLEV+1) PSUDU(JL) = 0.0_JPRB PPARF(JL) = 0.0_JPRB PPARCF(JL)= 0.0_JPRB PUVDF(JL) = 0.0_JPRB PSFSWDIR(JL,:)=0.0_JPRB PSFSWDIF(JL,:)=0.0_JPRB IBAS(JL) = INT ( 0.01_JPRB + PNBAS(JL) ) ITOP(JL) = INT ( 0.01_JPRB + PNTOP(JL) ) ENDDO !* 1.1 INITIALIZE VARIOUS FIELDS ! ------------------------- DO JSW=1,NSW DO JL = KIDIA,KFDIA ZALBD(JL,JSW)=PALBD(JL,JSW) ZALBP(JL,JSW)=PALBP(JL,JSW) ENDDO ENDDO DO JL = KIDIA,KFDIA ZEMIS(JL) =PEMIS(JL) ZEMIW(JL) =PEMIW(JL) ZMU0(JL) =PMU0(JL) ENDDO DO JK = 1 , KLEV JKP1 = JK + 1 JKL = KLEV+ 1 - JK JKLP1 = JKL + 1 DO JL = KIDIA,KFDIA ZPMB(JL,JK+1)=PAPH(JL,JKL)/100.0_JPRB !-- ZOZ in cm.atm for SW scheme ZOZ(JL,JK) = POZON(JL,JKL) * 46.6968_JPRB / RG ZCLD0(JL,JK) = 0.0_JPRB ZFCUP(JL,JK) = 0.0_JPRB ZFCDWN(JL,JK) = 0.0_JPRB ZFSUP(JL,JK) = 0.0_JPRB ZFSDWN(JL,JK) = 0.0_JPRB PFLUX(JL,1,JK) = 0.0_JPRB PFLUX(JL,2,JK) = 0.0_JPRB PFLUC(JL,1,JK) = 0.0_JPRB PFLUC(JL,2,JK) = 0.0_JPRB ENDDO ENDDO DO JK=1,KLEV JKL=KLEV+1-JK JKLP1=JKL+1 DO JL=KIDIA,KFDIA ZTL(JL,JK)=PTH(JL,JKLP1) ZTAVE(JL,JK)=PT(JL,JKL) ENDDO ENDDO DO JL=KIDIA,KFDIA ZTL(JL,KLEV+1)= PTH(JL,1) ZPMB(JL,KLEV+1) = PAPH(JL,1)/100.0_JPRB ENDDO !*** ! ------------------------------------------------------------------ !* 2. CLOUD AND AEROSOL PARAMETERS ! ---------------------------- DO JK = 1 , KLEV IKL = KLEV + 1 - JK ! 2.1 INITIALIZE OPTICAL PROPERTIES TO CLEAR SKY VALUES ! ------------------------------------------------- DO JSW = 1,NSW DO JL = KIDIA,KFDIA ZTAU(JL,JSW,JK) = 0.0_JPRB ZOMEGA(JL,JSW,JK)= 1.0_JPRB ZCG(JL,JSW,JK) = 0.0_JPRB ENDDO ENDDO DO JL = KIDIA,KFDIA ZCLDSW(JL,JK) = 0.0_JPRB ZCLDLD(JL,JK) = 0.0_JPRB ZCLDLU(JL,JK) = 0.0_JPRB ENDDO ! 2.2 CLOUD ICE AND LIQUID CONTENT AND PATH ! ------------------------------------- DO JL = KIDIA,KFDIA ! --- LIQUID WATER CONTENT (g.m-3) AND LIQUID WATER PATH (g.m-2) IF (PCLFR(JL,IKL) > REPSC ) THEN ZLWGKG=MAX(PQLWP(JL,IKL)*1000.0_JPRB,0.0_JPRB) ZIWGKG=MAX(PQIWP(JL,IKL)*1000.0_JPRB,0.0_JPRB) ZLWGKG=ZLWGKG/PCLFR(JL,IKL) ZIWGKG=ZIWGKG/PCLFR(JL,IKL) ELSE ZLWGKG=0.0_JPRB ZIWGKG=0.0_JPRB ENDIF ZRWGKG=0.0_JPRB ZRAINT(JL)=0.0_JPRB ! --- RAIN LIQUID WATER CONTENT (g.m-3) AND LIQUID WATER PATH (g.m-2) ! IF (PRAINT(JL,IKL) >= REPSCW) THEN ! ZRWGKG=MAX(PQRAIN(JL,IKL)*1000., 0.0) ! ZRAINT(JL)=PRAINT(JL,IKL)*3600.*1000. !- no radiative effect of rain (for the moment) ! ZRWGKG=0. ! ZRAINT(JL)=0. ! =========================================================== ! Modifications Martin et al. ! ELSE ! ENDIF ZDPOG=PDP(JL,IKL)/RG ZFLWP(JL)= ZLWGKG*ZDPOG ZFIWP(JL)= ZIWGKG*ZDPOG ZFRWP(JL)= ZRWGKG*ZDPOG ZPODT=PAP(JL,IKL)/(RD*PT(JL,IKL)) ZLWC(JL)=ZLWGKG*ZPODT ZIWC(JL)=ZIWGKG*ZPODT ! ZRWC(JL)=ZRWGKG*ZPODT ENDDO DO JL = KIDIA,KFDIA ! --- EFFECTIVE RADIUS FOR WATER, ICE AND RAIN PARTICLES ! very old parametrization as f(pressure) IF (NRADLP == 0) THEN !-- very old parametrization as f(pressure) ERA-15 ZRADLP(JL)=10.0_JPRB + (100000.0_JPRB-PAP(JL,IKL))*3.5_JPRB ELSEIF (NRADLP == 1) THEN ! simple distinction between land (10) and ocean (13) Zhang and Rossow IF (PLSM(JL) < 0.5_JPRB) THEN ZRADLP(JL)=13.0_JPRB ELSE ZRADLP(JL)=10.0_JPRB ENDIF ELSEIF (NRADLP == 2) THEN !-- based on Martin et al., 1994, JAS IF (PLSM(JL) < 0.5_JPRB) THEN IF (LCCNO) THEN ! ZASEA=50.0_JPRB ZASEA=PCCNO(JL) ELSE ZASEA=RCCNSEA ENDIF ZD=0.33_JPRB ZNTOT=-1.15E-03_JPRB*ZASEA*ZASEA+0.963_JPRB*ZASEA+5.30_JPRB ELSE IF (LCCNL) THEN ! ZALND=900.0_JPRB ZALND=PCCNL(JL) ELSE ZALND=RCCNLND ENDIF ZD=0.43_JPRB ZNTOT=-2.10E-04_JPRB*ZALND*ZALND+0.568_JPRB*ZALND-27.9_JPRB ENDIF ZNUM=3.0_JPRB*ZLWC(JL)*(1.0_JPRB+3.0_JPRB*ZD*ZD)**2 ZDEN=4.0_JPRB*RPI*ZNTOT*(1.0_JPRB+ZD*ZD)**3 IF((ZNUM/ZDEN) > REPLOG)THEN ZRADLP(JL)=100.0_JPRB*EXP(0.333_JPRB*LOG(ZNUM/ZDEN)) ZRADLP(JL)=MAX(ZRADLP(JL), 4.0_JPRB) ZRADLP(JL)=MIN(ZRADLP(JL),16.0_JPRB) ELSE ZRADLP(JL)=4.0_JPRB ENDIF ELSEIF (NRADLP == 3) THEN ! one uses the cloud droplet radius from newmicro ! IKL or JK ?? - I think IKL but needs to be verified > ref_liq_i ! (inverted) is used in the call of RECMWF_AERO in radlwsw_m.F90, ! so everything is fine - JBM 6/2019 ZRADLP(JL)=PREF_LIQ(JL,IKL) ENDIF ! =========================================================== ! ___________________________________________________________ ! rain drop from : unused as ZRAINT is 0. ! ZRADRD(JL)=500.0_JPRB*ZRAINT(JL)**0.22_JPRB ! IF (ZFLWP(JL).GT.0.) THEN ! ZRADRD(JL)=ZRADLP(JL)+ZRADRD(JL) ! ENDIF ENDDO DO JL = KIDIA,KFDIA ! diagnosing the ice particle effective radius/diameter !- ice particle effective radius =f(T) from Liou and Ou (1994) IF (PT(JL,IKL) < RTICE) THEN ZTEMPC=PT(JL,IKL)-RTT ELSE ZTEMPC=RTICE-RTT ENDIF ZRADIP(JL)=326.3_JPRB+ZTEMPC*(12.42_JPRB + ZTEMPC*(0.197_JPRB + ZTEMPC*& & 0.0012_JPRB)) IF (NRADIP == 0) THEN !-- fixed 40 micron effective radius ZRADIP(JL)= 40.0_JPRB ZDESR(JL) = ZDefRe * ZRADIP(JL) ELSEIF (NRADIP == 1) THEN !-- old formulation based on Liou & Ou (1994) temperature (40-130microns) ZRADIP(JL)=MAX(ZRADIP(JL),40.0_JPRB) ZDESR(JL) = ZDefRe * ZRADIP(JL) ELSEIF (NRADIP == 2) THEN !-- formulation following Jakob, Klein modifications to ice content ZRADIP(JL)=MAX(ZRADIP(JL),30.0_JPRB) ZRADIP(JL)=MIN(ZRADIP(JL),60.0_JPRB) ZDESR(JL)= ZDefRe * ZRADIP(JL) ELSEIF (NRADIP == 3 ) THEN !- ice particle effective radius =f(T,IWC) from Sun and Rikus (1999) ! revised by Sun (2001) IF (ZIWC(JL) > 0.0_JPRB ) THEN ZTEMPC = PT(JL,IKL)-83.15_JPRB ZTCELS = PT(JL,IKL)-RTT ZFSR = 1.2351_JPRB +0.0105_JPRB * ZTCELS ! Sun, 2001 (corrected from Sun & Rikus, 1999) ZAIWC = 45.8966_JPRB * ZIWC(JL)**0.2214_JPRB ZBIWC = 0.7957_JPRB * ZIWC(JL)**0.2535_JPRB ZDESR(JL) = ZFSR * (ZAIWC + ZBIWC*ZTEMPC) !-new ZDESR(JL) = MIN ( MAX( ZDESR(JL), 30.0_JPRB), 155.0_JPRB) ZDESR(JL) = MIN ( MAX( ZDESR(JL), 45.0_JPRB), 350.0_JPRB) ZRADIP(JL)= ZRefDe * ZDESR(JL) ELSE ! ZDESR(JL) = 92.5_JPRB ZDESR(JL) = 80.0_JPRB ZRADIP(JL)= ZRefDe * ZDESR(JL) ENDIF ELSEIF (NRADIP == 4 ) THEN ! one uses the cloud droplet radius from newmicro ! IKL or JK ?? - I think IKL but needs to be verified ZRADIP(JL)=PREF_ICE(JL,IKL) ENDIF ENDDO ! 2.3 CLOUD SHORTWAVE OPTICAL PROPERTIES ! ---------------------------------- ! ------------------------- ! --+ SW OPTICAL PARAMETERS + Water clouds after Fouquart (1987) ! ------------------------- Ice clouds (Ebert, Curry, 1992) DO JSW=1,NSW DO JL = KIDIA,KFDIA ZTOL=0.0_JPRB ZGL =0.0_JPRB ZOL =0.0_JPRB ZTOI=0.0_JPRB ZGI =0.0_JPRB ZOI =0.0_JPRB ZTOR=0.0_JPRB ZGR =0.0_JPRB ZOR =0.0_JPRB IF (ZFLWP(JL)+ZFIWP(JL)+ZFRWP(JL) > 2.0_JPRB * REPSCW ) THEN IF (ZFLWP(JL) >= REPSCW ) THEN IF (NLIQOPT /= 0 ) THEN !-- SW: Slingo, 1989 ZTOL = ZFLWP(JL)*(RASWCA(JSW)+RASWCB(JSW)/ZRADLP(JL)) ZGL = RASWCE(JSW)+RASWCF(JSW)*ZRADLP(JL) ZOL = 1. - RASWCC(JSW)-RASWCD(JSW)*ZRADLP(JL) ELSE !-- SW: Fouquart, 1991 ZTOL = ZFLWP(JL)*(RYFWCA(JSW)+RYFWCB(JSW)/ZRADLP(JL)) ZGL = RYFWCF(JSW) ! ZOL = RYFWCC(JSW)-RYFWCD(JSW)*EXP(-RYFWCE(JSW)*ZTOL) !-- NB: RSWINHF is there simply for making the CY29R2 branch bit compatible with ! the previous. Should be cleaned when RRTM_SW becomes active ZOL = RYFWCC(JSW)-RYFWCD(JSW)*EXP(-RYFWCE(JSW)*ZTOL*RSWINHF) ENDIF ENDIF IF (ZFIWP(JL) >= REPSCW ) THEN IF (NICEOPT <= 1) THEN !-- SW: Ebert-Curry ZTOI = ZFIWP(JL)*(REBCUA(JSW)+REBCUB(JSW)/ZRADIP(JL)) ZGI = REBCUE(JSW)+REBCUF(JSW)*ZRADIP(JL) ZOI = 1.0_JPRB - REBCUC(JSW)-REBCUD(JSW)*ZRADIP(JL) ELSEIF (NICEOPT == 2) THEN !-- SW: Fu-Liou 1993 Z1RADI = 1.0_JPRB / ZDESR(JL) ZBETAI = RFLAA0(JSW)+Z1RADI* RFLAA1(JSW) ZTOI = ZFIWP(JL) * ZBETAI ZOMGI= RFLBB0(JSW)+ZRADIP(JL)*(RFLBB1(JSW) + ZRADIP(JL) & & *(RFLBB2(JSW)+ZRADIP(JL)* RFLBB3(JSW) )) ZOI = 1.0_JPRB - ZOMGI ZOMGP= RFLCC0(JSW)+ZRADIP(JL)*(RFLCC1(JSW) + ZRADIP(JL) & & *(RFLCC2(JSW)+ZRADIP(JL)* RFLCC3(JSW) )) ZFDEL= RFLDD0(JSW)+ZRADIP(JL)*(RFLDD1(JSW) + ZRADIP(JL) & & *(RFLDD2(JSW)+ZRADIP(JL)* RFLDD3(JSW) )) ZGI = ((1.0_JPRB -ZFDEL)*ZOMGP + ZFDEL*3.0_JPRB) / 3.0_JPRB ELSEIF (NICEOPT == 3) THEN !-- SW: Fu 1996 Z1RADI = 1.0_JPRB / ZDESR(JL) ZBETAI = RFUAA0(JSW)+Z1RADI* RFUAA1(JSW) ZTOI = ZFIWP(JL) * ZBETAI ZOMGI= RFUBB0(JSW)+ZDESR(JL)*(RFUBB1(JSW) + ZDESR(JL) & & *(RFUBB2(JSW)+ZDESR(JL)* RFUBB3(JSW) )) ZOI = 1.0_JPRB - ZOMGI ZGI = RFUCC0(JSW)+ZDESR(JL)*(RFUCC1(JSW) + ZDESR(JL) & & *(RFUCC2(JSW)+ZDESR(JL)* RFUCC3(JSW) )) ZGI = MIN(1.0_JPRB, ZGI) ENDIF ENDIF ! IF (ZFRWP(JL) >= REPSCW ) THEN ! ZTOR= ZFRWP(JL)*0.003_JPRB * ZRAINT(JL)**(-0.22_JPRB) ! ZOR = 1.0_JPRB - RROMA(JSW)*ZRAINT(JL)**RROMB(JSW) ! ZGR = RRASY(JSW) ! ENDIF ! - MIX of WATER and ICE CLOUDS ZTAUMX= ZTOL + ZTOI + ZTOR ZOMGMX= ZTOL*ZOL + ZTOI*ZOI + ZTOR*ZOR ZASYMX= ZTOL*ZOL*ZGL + ZTOI*ZOI*ZGI + ZTOR*ZOR*ZGR ZASYMX= ZASYMX/ZOMGMX ZOMGMX= ZOMGMX/ZTAUMX ! --- SW FINAL CLOUD OPTICAL PARAMETERS ZCLDSW(JL,JK) = PCLFR(JL,IKL) ZTAU(JL,JSW,JK) = ZTAUMX ZOMEGA(JL,JSW,JK)= ZOMGMX ZCG(JL,JSW,JK) = ZASYMX ENDIF ENDDO ENDDO IF(LLDEBUG) THEN call writefield_phy("radlsw_ztau",ztau(:,1,:),klev) ENDIF ! 2.4 CLOUD LONGWAVE OPTICAL PROPERTIES FOR EC-OPE ! -------------------------------------------- ! ------------------------- ! --+ LW OPTICAL PARAMETERS + Water (and Ice) from Smith and Shi (1992) ! ------------------------- Ice clouds (Ebert, Curry, 1992) IF (.NOT.LRRTM) THEN DO JL = KIDIA,KFDIA ZALFICE(JL)=0.0_JPRB ZGAMICE(JL)=0.0_JPRB ZBICE(JL)=0.0_JPRB ZTICE(JL)=(PT(JL,IKL)-TSTAND)/TSTAND IF (NICEOPT == 1) THEN ZBICFU(JL)=1.0_JPRB ELSE ZBICFU(JL)=0.0_JPRB ENDIF ZKICFU(JL)=0.0_JPRB ENDDO DO JNU= 1,NSIL DO JL = KIDIA,KFDIA ZRES(JL) = XP(1,JNU)+ZTICE(JL)*(XP(2,JNU)+ZTICE(JL)*(XP(3,& & JNU)& & +ZTICE(JL)*(XP(4,JNU)+ZTICE(JL)*(XP(5,JNU)+ZTICE(JL)*(XP(6,& & JNU)& & ))))) ZBICE(JL) = ZBICE(JL) + ZRES(JL) ZGAMICE(JL) = ZGAMICE(JL) + REBCUI(JNU)*ZRES(JL) ZALFICE(JL) = ZALFICE(JL) + REBCUJ(JNU)*ZRES(JL) ENDDO ENDDO !-- Fu et al. (1998) with M'91 LW scheme IF (NICEOPT == 2 .OR. NICEOPT == 3) THEN DO JRTM=1,16 DO JL=KIDIA,KFDIA IF (PT(JL,IKL) < 160.0_JPRB) THEN INDLAY=1 ZTBLAY =PT(JL,IKL)-160.0_JPRB ELSEIF (PT(JL,IKL) < 339.0_JPRB ) THEN INDLAY=PT(JL,IKL)-159.0_JPRB INDLAY=MAX(INDLAY,1) ZTBLAY =PT(JL,IKL)-INT(PT(JL,IKL)) ELSE INDLAY=180 ZTBLAY =PT(JL,IKL)-339.0_JPRB ENDIF ZADDPLK = TOTPLNK(INDLAY+1,JRTM)-TOTPLNK(INDLAY,JRTM) ZPLANCK = DELWAVE(JRTM) * (TOTPLNK(INDLAY,JRTM) + ZTBLAY*ZADDPLK) ZBICFU(JL) = ZBICFU(JL) + ZPLANCK IF (ZIWC(JL) > 0.0_JPRB ) THEN ZRATIO = 1.0_JPRB / ZDESR(JL) IF (NICEOPT == 2) THEN ! ice cloud spectral emissivity a la Fu & Liou (1993) ZMABSD = RFULIO(JRTM,1) + ZRATIO & & *(RFULIO(JRTM,2) + ZRATIO*RFULIO(JRTM,3)) ! ice cloud spectral emissivity a la Fu et al (1998) ELSEIF (NICEOPT == 3) THEN ZMABSD = RFUETA(JRTM,1) + ZRATIO & & *(RFUETA(JRTM,2) + ZRATIO*RFUETA(JRTM,3)) ENDIF ZKICFU(JL) = ZKICFU(JL)+ ZMABSD*ZPLANCK ENDIF ENDDO ENDDO ENDIF DO JL = KIDIA,KFDIA ZGAMICE(JL) = ZGAMICE(JL) / ZBICE(JL) ZALFICE(JL) = ZALFICE(JL) / ZBICE(JL) ZKICFU(JL) = ZKICFU(JL) / ZBICFU(JL) IF (ZFLWP(JL)+ZFIWP(JL) > REPSCW) THEN IF (NLIQOPT == 0) THEN ! water cloud emissivity a la Smith & Shi (1992) ZMULTL=1.2_JPRB-0.006_JPRB*ZRADLP(JL) ZMSALD= 0.158_JPRB*ZMULTL ZMSALU= 0.130_JPRB*ZMULTL ELSE ! water cloud emissivity a la Savijarvi (1997) ZMSALU= 0.2441_JPRB-0.0105_JPRB*ZRADLP(JL) ZMSALD= 1.2154_JPRB*ZMSALU ENDIF IF (NICEOPT == 0) THEN ! ice cloud emissivity a la Smith & Shi (1992) ZMULTI=1.2_JPRB-0.006_JPRB*ZRADIP(JL) ZMSAID= 0.113_JPRB*ZMULTI ZMSAIU= 0.093_JPRB*ZMULTI ELSEIF (NICEOPT == 1) THEN ! ice cloud emissivity a la Ebert & Curry (1992) ZMSAID= 1.66_JPRB*(ZALFICE(JL)+ZGAMICE(JL)/ZRADIP(JL)) ZMSAIU= ZMSAID ELSEIF (NICEOPT == 2 .OR. NICEOPT == 3) THEN ! ice cloud emissivity a la Fu & Liou (1993) or Fu et al. (1998) ZMSAID= 1.66_JPRB*ZKICFU(JL) ZMSAIU= ZMSAID ENDIF IF (NINHOM == 1) THEN ZZFLWP= ZFLWP(JL) * RLWINHF ZZFIWP= ZFIWP(JL) * RLWINHF ELSE ZZFLWP= ZFLWP(JL) ZZFIWP= ZFIWP(JL) ENDIF ! effective cloudiness accounting for condensed water ZCLDLD(JL,JK) = PCLFR(JL,IKL)*(1.0_JPRB-EXP(-ZMSALD*ZZFLWP-ZMSAID* & & ZZFIWP)) ZCLDLU(JL,JK) = PCLFR(JL,IKL)*(1.0_JPRB-EXP(-ZMSALU*ZZFLWP-ZMSAIU* & & ZZFIWP)) ENDIF ENDDO ELSE ! 2.5 CLOUD LONGWAVE OPTICAL PROPERTIES FOR RRTM ! ------------------------------------------ ! ------------------------- ! --+ LW OPTICAL PARAMETERS + Water (and Ice) from Savijarvi (1998) ! ------------------------- Ice clouds (Ebert, Curry, 1992) ! No need for a fixed diffusivity factor, accounted for spectrally below ! The detailed spectral structure does not require defining upward and ! downward effective optical properties DO JRTM=1,16 DO JL = KIDIA,KFDIA ZTAUCLD(JL,JK,JRTM) = 0.0_JPRB ZMSALD = 0.0_JPRB ZMSAID = 0.0_JPRB IF (ZFLWP(JL)+ZFIWP(JL) > REPSCW) THEN IF (NLIQOPT == 0 .OR. NLIQOPT >= 3 ) THEN ! water cloud total emissivity a la Smith and Shi (1992) ZMULTL=1.2_JPRB-0.006_JPRB*ZRADLP(JL) ZRSALD= 0.144_JPRB*ZMULTL / 1.66_JPRB ELSEIF (NLIQOPT == 1) THEN ! water cloud spectral emissivity a la Savijarvi (1997) ZRSALD= RHSAVI(JRTM,1) + ZRADLP(JL)& & *(RHSAVI(JRTM,2) + ZRADLP(JL)*RHSAVI(JRTM,3)) ELSEIF (NLIQOPT == 2) THEN ! water cloud spectral emissivity a la Lindner and Li (2000) Z1RADL = 1.0_JPRB / ZRADLP(JL) ZEXTCF = RLILIA(JRTM,1)+ZRADLP(JL)*RLILIA(JRTM,2)+ Z1RADL*& & (RLILIA(JRTM,3) + Z1RADL*(RLILIA(JRTM,4) + Z1RADL*& & RLILIA(JRTM,5) )) Z1MOMG = RLILIB(JRTM,1) + Z1RADL*RLILIB(JRTM,2) & & + ZRADLP(JL) *(RLILIB(JRTM,3) + ZRADLP(JL)*RLILIB(JRTM,4) ) ZRSALD = Z1MOMG * ZEXTCF ENDIF IF (NICEOPT == 0) THEN ! ice cloud spectral emissivity a la Smith & Shi (1992) ZMULTI=1.2_JPRB-0.006_JPRB*ZRADIP(JL) ZRSAID= 0.103_JPRB*ZMULTI / 1.66_JPRB ELSEIF (NICEOPT == 1) THEN ! ice cloud spectral emissivity a la Ebert-Curry (1992) ZRSAID= REBCUH(JRTM)+REBCUG(JRTM)/ZRADIP(JL) ELSEIF (NICEOPT == 2) THEN ! ice cloud spectral emissivity a la Fu & Liou (1993) Z1RADI = 1.0_JPRB / ZDESR(JL) ZRSAID = RFULIO(JRTM,1) + Z1RADI & & *(RFULIO(JRTM,2) + Z1RADI * RFULIO(JRTM,3)) ELSEIF (NICEOPT == 3) THEN ! ice cloud spectral emissivity a la Fu et al (1998) including ! parametrisation for LW scattering effect Z1RADI = 1.0_JPRB / ZDESR(JL) ZRSAIE = RFUETA(JRTM,1) + Z1RADI & &*(RFUETA(JRTM,2) + Z1RADI * RFUETA(JRTM,3)) ZRSAIA = Z1RADI*(RFUETB(JRTM,1) +ZDESR(JL)*( RFUETB(JRTM,2) +ZDESR(JL)*( RFUETB(JRTM,3) +ZDESR(JL)* RFUETB(JRTM,4)))) ZRSAIG = RFUETC(JRTM,1) +ZDESR(JL)*( RFUETC(JRTM,2) +ZDESR(JL)*( RFUETC(JRTM,3) +ZDESR(JL)* RFUETC(JRTM,4))) ZRSAIF = 0.5_JPRB + ZRSAIG*( 0.3738_JPRB + ZRSAIG*( 0.0076_JPRB + ZRSAIG*0.1186_JPRB ) ) ZRSAID = (1.0_JPRB - ZRSAIA/ZRSAIE * ZRSAIF) * ZRSAIE ENDIF ZTAUD = ZRSALD*ZFLWP(JL)+ZRSAID*ZFIWP(JL) ! Diffusivity correction within clouds a la Savijarvi IF (LDIFFC) THEN ZDIFFD=MIN(MAX(1.517_JPRB-0.156_JPRB*LOG(ZTAUD) , 1.0_JPRB), & & 2.0_JPRB) ELSE ZDIFFD=1.66_JPRB ENDIF ZTAUCLD(JL,JK,JRTM) = ZTAUD*ZDIFFD ENDIF ENDDO ENDDO ENDIF ENDDO NUAER = NUA NTRAER = NTRA ! ------------------------------------------------------------------ ! ! 2.6 SCALING OF OPTICAL THICKNESS ! SPECTRALLY, ACCOUNTING FOR VERTICAL VARIABILITY JEXPLR=NLAYINH JXPLDN=2*JEXPLR+1 IF (NINHOM == 1) THEN !-- simple scaling a la Tiedtke (1996) with RSWINHF in SW and RLWINHF in LW DO JSW=1,NSW DO JK=1,KLEV DO JL=KIDIA,KFDIA ZTAU(JL,JSW,JK)=ZTAU(JL,JSW,JK) * RSWINHF ENDDO ENDDO ENDDO DO JRTM=1,16 DO JK=1,KLEV DO JL=KIDIA,KFDIA ZTAUCLD(JL,JK,JRTM)=ZTAUCLD(JL,JK,JRTM) * RLWINHF ENDDO ENDDO ENDDO ELSEIF (JEXPLR /= 0) THEN DO JSW=1,NSW DO JK=1,KLEV DO JL=KIDIA,KFDIA ZSQUAR(JL,JK)=0.0_JPRB ZVARIA(JL,JK)=1.0_JPRB ENDDO ENDDO !-- range should be defined from Hogan & Illingworth DO JK=1+JEXPLR,KLEV-JEXPLR DO JL=KIDIA,KFDIA ! ZAVDP(JL)=0.0_JPRB ZAVTO(JL)=0.0_JPRB ZSQTO(JL)=0.0_JPRB ENDDO DO JKI=JK-JEXPLR,JK+JEXPLR IKI=KLEV+1-JKI DO JL=KIDIA,KFDIA ! ZAVDP(JL)=ZAVDP(JL)+PDP(JL,IKI)/RG ZAVTO(JL)=ZAVTO(JL)+ZTAU(JL,JSW,JKI) ENDDO ENDDO DO JL=KIDIA,KFDIA ! ZAVTO(JL)=ZAVTO(JL)/ZAVDP(JL) ZAVTO(JL)=ZAVTO(JL)/JXPLDN ENDDO DO JKI=JK-JEXPLR,JK+JEXPLR IKI=KLEV+1-JKI DO JL=KIDIA,KFDIA ! ZSQTO(JL)=ZSQTO(JL)+(ZTAU(JL,JSW,JKI)/PDP(JL,IKI)-ZAVTO(JL))**2 ZSQTO(JL)=ZSQTO(JL)+(ZTAU(JL,JSW,JKI)-ZAVTO(JL))**2 ENDDO ENDDO DO JL=KIDIA,KFDIA ZSQTO(JL)=SQRT(ZSQTO(JL)/(JXPLDN*(JXPLDN-1))) IF (ZAVTO(JL) > 0.0_JPRB) THEN ZVARIA(JL,JK)=(ZSQTO(JL)/ZAVTO(JL))**2 ZSQUAR(JL,JK)=EXP(-ZVARIA(JL,JK)) ELSE ZVARIA(JL,JK)=0.0_JPRB ZSQUAR(JL,JK)=1.0_JPRB ENDIF !-- scaling a la Barker IF (NINHOM ==2) THEN ZTAU(JL,JSW,JK)=ZTAU(JL,JSW,JK)*ZSQUAR(JL,JK) !-- scaling a la Cairns et al. ELSEIF (NINHOM == 3) THEN ZVI=ZVARIA(JL,JK) ZTAU(JL,JSW,JK) = ZTAU(JL,JSW,JK)/(1.0_JPRB+ZVI) ZOMEGA(JL,JSW,JK)= ZOMEGA(JL,JSW,JK) & & /(1.0_JPRB + ZVI*(1.0_JPRB-ZOMEGA(JL,JSW,JK) ) ) ZCG(JL,JSW,JK) = ZCG(JL,JSW,JK) & & *(1.0_JPRB+ZVI*(1.0_JPRB-ZOMEGA(JL,JSW,JK))) & & /(1.0_JPRB+ZVI*(1.0_JPRB-ZOMEGA(JL,JSW,JK)*ZCG(JL,JSW,JK))) ENDIF ENDDO ! JL=KIDIA ! print 9261,JSW,JK,ZTAU(JL,JSW,JK),ZAVTO(JL),ZSQTO(JL),ZVARIA(JL,JK),ZSQUAR(JL,JK) 9261 format(1x,'Varia1 ',2I3,7F10.4) ENDDO ENDDO DO JRTM=1,16 DO JK=1,KLEV DO JL=KIDIA,KFDIA ZSQUAR(JL,JK)=0.0_JPRB ZVARIA(JL,JK)=1.0_JPRB ENDDO ENDDO !-- range to be defined from Hogan & Illingworth DO JK=1+JEXPLR,KLEV-JEXPLR DO JL=KIDIA,KFDIA ! ZAVDP(JL)=0.0_JPRB ZAVTO(JL)=0.0_JPRB ZSQTO(JL)=0.0_JPRB ENDDO DO JKI=JK-JEXPLR,JK+JEXPLR IKI=KLEV+1-JKI DO JL=KIDIA,KFDIA ! ZAVDP(JL)=ZAVDP(JL)+PDP(JL,IKI)/RG ZAVTO(JL)=ZAVTO(JL)+ZTAUCLD(JL,JKI,JRTM) ENDDO ENDDO DO JL=KIDIA,KFDIA ! ZAVTO(JL)=ZAVTO(JL)/ZAVDP(JL) ZAVTO(JL)=ZAVTO(JL)/JXPLDN ENDDO DO JKI=JK-JEXPLR,JK+JEXPLR IKI=KLEV+1-JKI DO JL=KIDIA,KFDIA ! ZSQTO(JL)=ZSQTO(JL)+(ZTAUCLD(JL,JKI,JRTM)/PDP(JL,IKI)-ZAVTO(JL))**2 ZSQTO(JL)=ZSQTO(JL)+(ZTAUCLD(JL,JKI,JRTM)-ZAVTO(JL))**2 ENDDO ENDDO DO JL=KIDIA,KFDIA ZSQTO(JL)=SQRT(ZSQTO(JL)/(JXPLDN*(JXPLDN-1))) IF (ZAVTO(JL) > 0.0_JPRB) THEN ZVARIA(JL,JK)=(ZSQTO(JL)/ZAVTO(JL))**2 ZSQUAR(JL,JK)=EXP(-ZVARIA(JL,JK)) ELSE ZVARIA(JL,JK)=0.0_JPRB ZSQUAR(JL,JK)=1.0_JPRB ENDIF !-- scaling a la Barker IF (NINHOM ==2) THEN ZTAUCLD(JL,JK,JRTM)=ZTAUCLD(JL,JK,JRTM)*ZSQUAR(JL,JK) !-- scaling a la Cairns et al. ELSEIF (NINHOM == 3) THEN ZVI=ZVARIA(JL,JK) ZTAUCLD(JL,JK,JRTM)=ZTAUCLD(JL,JK,JRTM)/(1.0_JPRB+ZVI) ENDIF ENDDO ! JL=KIDIA ! print 9262,JRTM,JK,ZTAUCLD(JL,JK,JRTM),ZAVTO(JL),ZSQTO(JL),ZVARIA(JL,JK),ZSQUAR(JL,JK) 9262 format(1x,'Varia2 ',2I3,7F10.4) ENDDO ENDDO ENDIF ! ------------------------------------------------------------------ !* 2.7 DIFFUSIVITY FACTOR OR SATELLITE VIEWING ANGLE ! --------------------------------------------- DO JL = KIDIA,KFDIA ZVIEW(JL) = DIFF ENDDO ! ------------------------------------------------------------------ !* 3. CALL LONGWAVE RADIATION CODE ! ---------------------------- !* 3.1 FULL LONGWAVE RADIATION COMPUTATIONS ! ------------------------------------ !PRINT *,'RADLSW: LPHYLIN, LRRTM',LPHYLIN, LRRTM IF (.NOT.LPHYLIN) THEN IF ( .NOT. LRRTM) THEN CALL LW & & ( KIDIA , KFDIA , KLON , KLEV , KMODE,& & PCCO2 , ZCLDLD, ZCLDLU,& & PDP , ZDT0 , ZEMIS , ZEMIW,& & ZPMB , POZON , ZTL,& & PAER , ZTAVE , ZVIEW , PQ,& & ZEMIT , PFLUX , PFLUC & & ) ! PRINT *,'RADLSW: apres CALL LW' IF(LLDEBUG) THEN call writefield_phy('radlsw_flux1',PFLUX(:,1,:),klev+1) call writefield_phy('radlsw_flux2',PFLUX(:,2,:),klev+1) call writefield_phy('radlsw_fluc1',PFLUC(:,1,:),klev+1) call writefield_phy('radlsw_fluc2',PFLUC(:,2,:),klev+1) ENDIF ELSE !* 3.2 FULL LONGWAVE RADIATION COMPUTATIONS - RRTM ! ------------------------------------ ---- ! i) pass ZOZN (ozone mass mixing ratio) to RRTM; remove pressure ! weighting applied to POZON in driverMC (below) ! ii) pass ZEMIS and ZEMIW to RRTM; return ZEMIT from RRTM ! iii)pass ZTAUCLD, cloud optical depths (water+ice) to RRTM, ! computed from equations above ! iv) pass ECRT arrays to RRTM arrays in interface routine ECRTATM ! in module rrtm_ecrt.f DO JL = KIDIA,KFDIA DO JK = 1, KLEV ZOZN(JL,JK) = POZON(JL,JK)/PDP(JL,JK) ENDDO ENDDO ! PRINT *,'RADLSW: avant CALL RRTM_RRTM_140GP,PAP=',PAP(1,:) CALL RRTM_RRTM_140GP & & ( KIDIA , KFDIA , KLON , KLEV,& & PAER , PAPH , PAP,& & PTS , PTH , PT,& & ZEMIS , ZEMIW,& & PQ , PCCO2 , ZOZN ,& & ZCLDSW , ZTAUCLD,& & PTAU_LW,& & ZEMIT , PFLUX , PFLUC , ZTCLEAR ) ! PRINT *,'RADLSW: apres CALL RRTM_RRTM_140GP' ENDIF ELSE ZEMIT (:) = 0.0_JPRB PFLUX(:,:,:)= 0.0_JPRB PFLUC(:,:,:)= 0.0_JPRB ! PRINT *,'RADLSW: ZEMIT,PFLUX et PFLUC = 0' ENDIF ! ------------------------------------------------------------------ !* 4. CALL SHORTWAVE RADIATION CODE ! ----------------------------- ZRMUZ=0.0_JPRB DO JL = KIDIA,KFDIA ZRMUZ = MAX (ZRMUZ, ZMU0(JL)) ENDDO IF (NSTEP == 0 .AND. LEDBUG .AND. ZMU0(KIDIA) > 0.0_JPRB) THEN WRITE(NULOUT,'(4E15.8)') PRII0,PCCO2,ZPSOL(KIDIA),ZMU0(KIDIA) WRITE(NULOUT,'("ZALBD ",6E15.8)') (ZALBD(KIDIA,JSW),JSW=1,NSW) WRITE(NULOUT,'("ZALBP ",6E15.8)') (ZALBP(KIDIA,JSW),JSW=1,NSW) WRITE(NULOUT,'("PQ ",10E12.5)') (PQ(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("PQS ",10E12.5)') (PQS(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("PDP ",10E12.5)') (PDP(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZPMB ",10E12.5)') (ZPMB(KIDIA,JK),JK=1,KLEV+1) WRITE(NULOUT,'("ZTAVE ",10E12.5)') (ZTAVE(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZCLDSW",10E12.5)') (ZCLDSW(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZTAU ",10E12.5)') ((ZTAU(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) WRITE(NULOUT,'("ZCG ",10E12.5)') ((ZCG(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) WRITE(NULOUT,'("ZOMEGA",10E12.5)') ((ZOMEGA(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) WRITE(NULOUT,'("ZOZ ",10E12.5)') (ZOZ(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("PAER ",10E12.5)') ((PAER(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) ENDIF IF (NSTEP == 0 .AND. LEDBUG .AND. ZMU0(KIDIA) > 0.0_JPRB) THEN WRITE(NULOUT,'(4E15.8)') PRII0,PCCO2,ZPSOL(KIDIA),ZMU0(KIDIA) WRITE(NULOUT,'("ZALBD ",6E15.8)') (ZALBD(KIDIA,JSW),JSW=1,NSW) WRITE(NULOUT,'("ZALBP ",6E15.8)') (ZALBP(KIDIA,JSW),JSW=1,NSW) WRITE(NULOUT,'("PQ ",10E12.5)') (PQ(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("PQS ",10E12.5)') (PQS(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("PDP ",10E12.5)') (PDP(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZPMB ",10E12.5)') (ZPMB(KIDIA,JK),JK=1,KLEV+1) WRITE(NULOUT,'("ZTAVE ",10E12.5)') (ZTAVE(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZCLDSW",10E12.5)') (ZCLDSW(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZTAU ",10E12.5)') ((ZTAU(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) WRITE(NULOUT,'("ZCG ",10E12.5)') ((ZCG(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) WRITE(NULOUT,'("ZOMEGA",10E12.5)') ((ZOMEGA(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) WRITE(NULOUT,'("ZOZ ",10E12.5)') (ZOZ(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("PAER ",10E12.5)') ((PAER(KIDIA,JSW,JK),JK=1,KLEV),JSW=1,NSW) ENDIF CALL SW & & ( KIDIA , KFDIA , KLON , KLEV , KAER,& & PRII0 , PCCO2 , ZPSOL , ZALBD , ZALBP , PQ , PQS,& & ZMU0 , ZCG , ZCLDSW, PDP , ZOMEGA, ZOZ , ZPMB,& & ZTAU , ZTAVE , PAER,& & PFSDN , PFSUP , PFSCDN, PFSCUP,& & ZFSDNN, ZFSDNV, ZFSUPN, ZFSUPV,& & ZFCDNN, ZFCDNV, ZFCUPN, ZFCUPV,& & ZSUDU , ZUVDF , ZPARF ,ZPARCF, ZDIFFS, ZDIRFS, & & LRDUST,PPIZA_DST,PCGA_DST,PTAUREL_DST& & ) PFSDNV=ZFSDNV PFSDNN=ZFSDNN IF (SIZE(PSFSWDIR,2)>1) THEN PSFSWDIR= ZDIRFS PSFSWDIF= ZDIFFS ELSE PSFSWDIR (:,1) = ZFSDNV(:) + ZFSDNN(:) PSFSWDIF (:,:) = 0. ENDIF IF (NSTEP == 0 .AND. LEDBUG .AND. ZMU0(KIDIA) > 0.0_JPRB) THEN WRITE(NULOUT,'("ZFSDWN",10E12.5)') (ZFSDWN(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZFSUP ",10E12.5)') (ZFSUP (KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZFCDWN",10E12.5)') (ZFCDWN(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZFCUP ",10E12.5)') (ZFCUP (KIDIA,JK),JK=1,KLEV) LEDBUG=.FALSE. ENDIF IF (NSTEP == 0 .AND. LEDBUG .AND. ZMU0(KIDIA) > 0.0_JPRB) THEN WRITE(NULOUT,'("ZFSDWN",10E12.5)') (ZFSDWN(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZFSUP ",10E12.5)') (ZFSUP (KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZFCDWN",10E12.5)') (ZFCDWN(KIDIA,JK),JK=1,KLEV) WRITE(NULOUT,'("ZFCUP ",10E12.5)') (ZFCUP (KIDIA,JK),JK=1,KLEV) LEDBUG=.FALSE. ENDIF ! ------------------------------------------------------------------ !* 5. FILL UP THE MODEL NET LW AND SW RADIATIVE FLUXES ! ------------------------------------------------ DO JKL = 1 , KLEV+1 JK = KLEV+1 + 1 - JKL DO JL = KIDIA,KFDIA PFLS(JL,JKL) = ZFSDWN(JL,JK) - ZFSUP(JL,JK) PFLT(JL,JKL) = - PFLUX(JL,1,JK) - PFLUX(JL,2,JK) PFCS(JL,JKL) = ZFCDWN(JL,JK) - ZFCUP(JL,JK) PFCT(JL,JKL) = - PFLUC(JL,1,JK) - PFLUC(JL,2,JK) ENDDO ENDDO DO JL = KIDIA,KFDIA PFRSOD(JL)=ZFSDWN(JL,1) PEMIT (JL)=ZEMIT (JL) PSUDU (JL)=ZSUDU (JL) PUVDF (JL)=ZUVDF (JL) PPARF (JL)=ZPARF (JL) PPARCF(JL)=ZPARCF(JL) PTINCF(JL)=PRII0 * ZMU0(JL) ENDDO !print 9501,(PUVDF(JL),JL=KIDIA,KFDIA) 9501 format(1x,'RADLSW PUVDF: ',30f6.1) !print 9502,(PPARF(JL),JL=KIDIA,KFDIA) 9502 format(1x,'RADLSW PPARF: ',30f6.1) ! -------------------------------------------------------------- IF (LHOOK) CALL DR_HOOK('RADLSW',1,ZHOOK_HANDLE) END SUBROUTINE RADLSW