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! $Id: lwu.F90 3666 2020-04-20 10:13:34Z lfalletti $ |
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SUBROUTINE LWU & |
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& ( KIDIA, KFDIA, KLON, KLEV,& |
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& PAER , PCCO2, PDP , PPMB, PQOF , PTAVE, PVIEW, PWV,& |
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& PABCU & |
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& ) |
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!**** *LWU* - LONGWAVE EFFECTIVE ABSORBER AMOUNTS |
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! PURPOSE. |
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! -------- |
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! COMPUTES ABSORBER AMOUNTS INCLUDING PRESSURE AND |
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! TEMPERATURE EFFECTS |
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!** INTERFACE. |
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! ---------- |
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! EXPLICIT ARGUMENTS : |
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! -------------------- |
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! ==== INPUTS === |
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! PAER : (KLON,6,KLEV) ; OPTICAL THICKNESS OF THE AEROSOLS |
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! PCCO2 : ; CONCENTRATION IN CO2 (PA/PA) |
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! PDP : (KLON,KLEV) ; LAYER PRESSURE THICKNESS (PA) |
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! PPMB : (KLON,KLEV+1) ; HALF LEVEL PRESSURE |
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! PQOF : (KLON,KLEV) ; CONCENTRATION IN OZONE (PA/PA) |
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! PTAVE : (KLON,KLEV) ; TEMPERATURE |
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! PWV : (KLON,KLEV) ; SPECIFIC HUMIDITY PA/PA |
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! PVIEW : (KLON) ; COSECANT OF VIEWING ANGLE |
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! ==== OUTPUTS === |
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! PABCU :(KLON,NUA,3*KLEV+1); EFFECTIVE ABSORBER AMOUNTS |
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! IMPLICIT ARGUMENTS : NONE |
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! -------------------- |
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! METHOD. |
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! ------- |
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! 1. COMPUTES THE PRESSURE AND TEMPERATURE WEIGHTED AMOUNTS OF |
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! ABSORBERS. |
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! EXTERNALS. |
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! ---------- |
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! NONE |
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! REFERENCE. |
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! ---------- |
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! SEE RADIATION'S PART OF THE MODEL'S DOCUMENTATION AND |
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! ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE IFS |
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! AUTHOR. |
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! ------- |
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! JEAN-JACQUES MORCRETTE *ECMWF* |
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! MODIFICATIONS. |
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! -------------- |
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! ORIGINAL : 89-07-14 |
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! JJ Morcrette 97-04-18 Revised Continuum + Clean-up |
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! M.Hamrud 01-Oct-2003 CY28 Cleaning |
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!----------------------------------------------------------------------- |
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USE PARKIND1 ,ONLY : JPIM ,JPRB |
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USE YOMHOOK ,ONLY : LHOOK, DR_HOOK |
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USE YOMCST , ONLY : RG |
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USE YOESW , ONLY : RAER |
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USE YOELW , ONLY : NSIL ,NUA ,NG1 ,NG1P1 ,& |
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& ALWT ,BLWT ,RO3T ,RT1 ,TREF ,& |
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& RVGCO2 ,RVGH2O ,RVGO3 |
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!USE YOERDI , ONLY : RCH4 ,RN2O ,RCFC11 ,RCFC12 |
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USE YOERDU , ONLY : R10E ,REPSCO ,REPSCQ |
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IMPLICIT NONE |
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INTEGER(KIND=JPIM),INTENT(IN) :: KLON |
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INTEGER(KIND=JPIM),INTENT(IN) :: KLEV |
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INTEGER(KIND=JPIM),INTENT(IN) :: KIDIA |
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INTEGER(KIND=JPIM),INTENT(IN) :: KFDIA |
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REAL(KIND=JPRB) ,INTENT(IN) :: PAER(KLON,6,KLEV) |
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REAL(KIND=JPRB) ,INTENT(IN) :: PCCO2 |
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REAL(KIND=JPRB) ,INTENT(IN) :: PDP(KLON,KLEV) |
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REAL(KIND=JPRB) ,INTENT(IN) :: PPMB(KLON,KLEV+1) |
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REAL(KIND=JPRB) ,INTENT(IN) :: PQOF(KLON,KLEV) |
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REAL(KIND=JPRB) ,INTENT(IN) :: PTAVE(KLON,KLEV) |
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REAL(KIND=JPRB) ,INTENT(IN) :: PVIEW(KLON) |
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REAL(KIND=JPRB) ,INTENT(IN) :: PWV(KLON,KLEV) |
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REAL(KIND=JPRB) ,INTENT(OUT) :: PABCU(KLON,NUA,3*KLEV+1) |
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! $Id: clesphys.h 3435 2019-01-22 15:21:59Z fairhead $ |
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! |
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! ATTENTION!!!!: ce fichier include est compatible format fixe/format libre |
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! veillez \`a n'utiliser que des ! pour les commentaires |
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! et \`a bien positionner les & des lignes de continuation |
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! (les placer en colonne 6 et en colonne 73) |
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! |
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!..include cles_phys.h |
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! |
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INTEGER iflag_cycle_diurne |
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LOGICAL soil_model,new_oliq,ok_orodr,ok_orolf |
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LOGICAL ok_limitvrai |
106 |
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LOGICAL ok_all_xml |
107 |
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LOGICAL ok_lwoff |
108 |
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INTEGER nbapp_rad, iflag_con, nbapp_cv, nbapp_wk, iflag_ener_conserv |
109 |
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REAL co2_ppm, co2_ppm0, solaire |
110 |
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!FC |
111 |
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REAL Cd_frein |
112 |
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LOGICAL ok_suntime_rrtm |
113 |
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REAL(kind=8) RCO2, RCH4, RN2O, RCFC11, RCFC12 |
114 |
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REAL(kind=8) RCO2_act, RCH4_act, RN2O_act, RCFC11_act, RCFC12_act |
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REAL(kind=8) CH4_ppb, N2O_ppb, CFC11_ppt, CFC12_ppt |
116 |
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!IM ajout CFMIP2/CMIP5 |
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REAL(kind=8) RCO2_per,RCH4_per,RN2O_per,RCFC11_per,RCFC12_per |
118 |
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REAL(kind=8) CH4_ppb_per,N2O_ppb_per,CFC11_ppt_per,CFC12_ppt_per |
119 |
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120 |
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!OM ---> correction du bilan d'eau global |
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!OM Correction sur precip KE |
122 |
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REAL cvl_corr |
123 |
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!OM Fonte calotte dans bilan eau |
124 |
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LOGICAL ok_lic_melt |
125 |
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!OB Depot de vapeur d eau sur la calotte pour le bilan eau |
126 |
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LOGICAL ok_lic_cond |
127 |
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128 |
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!IM simulateur ISCCP |
129 |
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INTEGER top_height, overlap |
130 |
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!IM seuils cdrm, cdrh |
131 |
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REAL cdmmax, cdhmax |
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!IM param. stabilite s/ terres et en dehors |
133 |
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REAL ksta, ksta_ter, f_ri_cd_min |
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!IM ok_kzmin : clef calcul Kzmin dans la CL de surface cf FH |
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LOGICAL ok_kzmin |
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!IM, MAFo fmagic, pmagic : parametres - additionnel et multiplicatif - |
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! pour regler l albedo sur ocean |
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REAL pbl_lmixmin_alpha |
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REAL fmagic, pmagic |
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! Hauteur (imposee) du contenu en eau du sol |
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REAL qsol0,albsno0,evap0 |
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! Frottement au sol (Cdrag) |
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Real f_cdrag_ter,f_cdrag_oce |
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REAL min_wind_speed,f_gust_wk,f_gust_bl,f_qsat_oce,f_z0qh_oce |
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REAL z0m_seaice,z0h_seaice |
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INTEGER iflag_gusts,iflag_z0_oce |
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148 |
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! Rugoro |
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Real f_rugoro,z0min |
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151 |
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! tau_gl : constante de rappel de la temperature a la surface de la glace |
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REAL tau_gl |
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154 |
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!IM lev_histhf : niveau sorties 6h |
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!IM lev_histday : niveau sorties journalieres |
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!IM lev_histmth : niveau sorties mensuelles |
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!IM lev_histdayNMC : on peut sortir soit sur 8 (comme AR5) ou bien |
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! sur 17 niveaux de pression |
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INTEGER lev_histhf, lev_histday, lev_histmth |
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INTEGER lev_histdayNMC |
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Integer lev_histins, lev_histLES |
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!IM ok_histNMC : sortie fichiers niveaux de pression (histmthNMC, histdayNMC, histhfNMC) |
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!IM freq_outNMC : frequences de sortie fichiers niveaux de pression (histmthNMC, histdayNMC, histhfNMC) |
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!IM freq_calNMC : frequences de calcul fis. hist*NMC.nc |
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LOGICAL ok_histNMC(3) |
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INTEGER levout_histNMC(3) |
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REAL freq_outNMC(3) , freq_calNMC(3) |
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CHARACTER(len=4) type_run |
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! aer_type: pour utiliser un fichier constant dans readaerosol |
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CHARACTER(len=8) :: aer_type |
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LOGICAL ok_regdyn |
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REAL lonmin_ins, lonmax_ins, latmin_ins, latmax_ins |
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REAL ecrit_ins, ecrit_hf, ecrit_day |
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REAL ecrit_mth, ecrit_tra, ecrit_reg |
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REAL ecrit_LES |
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REAL freq_ISCCP, ecrit_ISCCP |
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REAL freq_COSP, freq_AIRS |
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LOGICAL :: ok_cosp,ok_mensuelCOSP,ok_journeCOSP,ok_hfCOSP |
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LOGICAL :: ok_airs |
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INTEGER :: ip_ebil_phy, iflag_rrtm, iflag_ice_thermo, NSW, iflag_albedo |
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LOGICAL :: ok_chlorophyll |
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LOGICAL :: ok_strato |
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LOGICAL :: ok_hines, ok_gwd_rando |
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LOGICAL :: ok_qch4 |
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LOGICAL :: ok_conserv_q |
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LOGICAL :: adjust_tropopause |
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LOGICAL :: ok_daily_climoz |
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! flag to bypass or not the phytrac module |
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INTEGER :: iflag_phytrac |
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COMMON/clesphys/ & |
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! REAL FIRST |
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& co2_ppm, solaire & |
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& , RCO2, RCH4, RN2O, RCFC11, RCFC12 & |
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& , RCO2_act, RCH4_act, RN2O_act, RCFC11_act, RCFC12_act & |
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& , RCO2_per, RCH4_per, RN2O_per, RCFC11_per, RCFC12_per & |
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& , CH4_ppb, N2O_ppb, CFC11_ppt, CFC12_ppt & |
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& , CH4_ppb_per, N2O_ppb_per, CFC11_ppt_per, CFC12_ppt_per & |
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& , cdmmax,cdhmax,ksta,ksta_ter,f_ri_cd_min,pbl_lmixmin_alpha & |
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& , fmagic, pmagic & |
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& , f_cdrag_ter,f_cdrag_oce,f_rugoro,z0min,tau_gl & |
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& , min_wind_speed,f_gust_wk,f_gust_bl,f_qsat_oce,f_z0qh_oce & |
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& , z0m_seaice,z0h_seaice & |
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& , freq_outNMC, freq_calNMC & |
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& , lonmin_ins, lonmax_ins, latmin_ins, latmax_ins & |
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& , freq_ISCCP, ecrit_ISCCP, freq_COSP, freq_AIRS & |
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& , cvl_corr & |
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& , qsol0,albsno0,evap0 & |
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& , co2_ppm0 & |
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!FC |
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& , Cd_frein & |
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& , ecrit_LES & |
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& , ecrit_ins, ecrit_hf, ecrit_day & |
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& , ecrit_mth, ecrit_tra, ecrit_reg & |
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! THEN INTEGER AND LOGICALS |
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& , top_height & |
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& , iflag_cycle_diurne, soil_model, new_oliq & |
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& , ok_orodr, ok_orolf, ok_limitvrai, nbapp_rad & |
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& , iflag_con, nbapp_cv, nbapp_wk & |
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& , iflag_ener_conserv & |
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& , ok_suntime_rrtm & |
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& , overlap & |
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& , ok_kzmin & |
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& , lev_histhf, lev_histday, lev_histmth & |
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& , lev_histins, lev_histLES, lev_histdayNMC, levout_histNMC & |
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& , ok_histNMC & |
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& , type_run, ok_regdyn, ok_cosp, ok_airs & |
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& , ok_mensuelCOSP,ok_journeCOSP,ok_hfCOSP & |
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& , ip_ebil_phy & |
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& , iflag_gusts ,iflag_z0_oce & |
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& , ok_lic_melt, ok_lic_cond, aer_type & |
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& , iflag_rrtm, ok_strato,ok_hines, ok_qch4 & |
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& , iflag_ice_thermo, ok_gwd_rando, NSW, iflag_albedo & |
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& , ok_chlorophyll,ok_conserv_q, adjust_tropopause & |
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& , ok_daily_climoz, ok_all_xml, ok_lwoff & |
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& , iflag_phytrac |
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save /clesphys/ |
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!$OMP THREADPRIVATE(/clesphys/) |
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!----------------------------------------------------------------------- |
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!* 0.1 ARGUMENTS |
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! --------- |
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!----------------------------------------------------------------------- |
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! ------------ |
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REAL(KIND=JPRB) :: ZABLY(KLON,7,3*KLEV+1) , ZDPM(KLON,3*KLEV)& |
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& , ZDUC(KLON, 3*KLEV+1) , ZFACT(KLON)& |
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& , ZUPM(KLON,3*KLEV) |
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REAL(KIND=JPRB) :: ZPHIO(KLON),ZPSC2(KLON) , ZPSC3(KLON), ZPSH1(KLON)& |
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& , ZPSH2(KLON),ZPSH3(KLON) , ZPSH4(KLON), ZPSH5(KLON)& |
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& , ZPSH6(KLON),ZPSIO(KLON) , ZTCON(KLON)& |
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& , ZPHM6(KLON),ZPSM6(KLON) , ZPHN6(KLON), ZPSN6(KLON) |
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REAL(KIND=JPRB) :: ZSSIG(KLON,3*KLEV+1) , ZTAVI(KLON)& |
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& , ZUAER(KLON,NSIL) , ZXOZ(KLON) , ZXWV(KLON) |
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INTEGER(KIND=JPIM) :: IAE1, IAE2, IAE3, IC, ICP1, IG1, IJ, IJPN,& |
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& IKIP1, IKJ, IKJP, IKJPN, IKJR, IKL, JA, JAE, & |
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& JK, JKI, JKK, JL |
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REAL(KIND=JPRB) :: ZALUP, ZCAC8, ZCAH1, ZCAH2, ZCAH3, ZCAH4,& |
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& ZCAH5, ZCAH6, ZCBC8, ZCBH1, ZCBH2, ZCBH3, & |
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& ZCBH4, ZCBH5, ZCBH6, ZDIFF, ZDPMG, ZDPMP0, & |
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& ZFPPW, ZTX, ZTX2, ZU6, ZUP, ZUPMCO2, ZUPMG, & |
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& ZUPMH2O, ZUPMO3, ZZABLY |
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REAL(KIND=JPRB) :: ZHOOK_HANDLE |
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!----------------------------------------------------------------------- |
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!* 1. INITIALIZATION |
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! -------------- |
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!----------------------------------------------------------------------- |
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!* 2. PRESSURE OVER GAUSS SUB-LEVELS |
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! ------------------------------ |
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IF (LHOOK) CALL DR_HOOK('LWU',0,ZHOOK_HANDLE) |
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DO JL = KIDIA,KFDIA |
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ZSSIG(JL, 1 ) = PPMB(JL,1) * 100._JPRB |
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ENDDO |
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DO JK = 1 , KLEV |
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IKJ=(JK-1)*NG1P1+1 |
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IKJR = IKJ |
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IKJP = IKJ + NG1P1 |
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DO JL = KIDIA,KFDIA |
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ZSSIG(JL,IKJP)=PPMB(JL,JK+1)* 100._JPRB |
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ENDDO |
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DO IG1=1,NG1 |
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IKJ=IKJ+1 |
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DO JL = KIDIA,KFDIA |
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ZSSIG(JL,IKJ)= (ZSSIG(JL,IKJR) + ZSSIG(JL,IKJP)) * 0.5_JPRB & |
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& + RT1(IG1) * (ZSSIG(JL,IKJP) - ZSSIG(JL,IKJR)) * 0.5_JPRB |
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ENDDO |
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ENDDO |
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ENDDO |
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!----------------------------------------------------------------------- |
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!* 4. PRESSURE THICKNESS AND MEAN PRESSURE OF SUB-LAYERS |
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! -------------------------------------------------- |
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306 |
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DO JKI=1,3*KLEV |
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IKIP1=JKI+1 |
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DO JL = KIDIA,KFDIA |
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ZUPM(JL,JKI)=(ZSSIG(JL,JKI)+ZSSIG(JL,IKIP1))*0.5_JPRB |
310 |
|
✗ |
ZDPM(JL,JKI)=(ZSSIG(JL,JKI)-ZSSIG(JL,IKIP1))/(10._JPRB*RG) |
311 |
|
|
ENDDO |
312 |
|
|
ENDDO |
313 |
|
|
|
314 |
|
✗ |
DO JK = 1 , KLEV |
315 |
|
✗ |
IKL = KLEV+1 - JK |
316 |
|
✗ |
DO JL = KIDIA,KFDIA |
317 |
|
✗ |
ZXWV(JL) = MAX (PWV(JL,IKL) , REPSCQ ) |
318 |
|
✗ |
ZXOZ(JL) = MAX (PQOF(JL,IKL) / PDP(JL,IKL) , REPSCO ) |
319 |
|
|
ENDDO |
320 |
|
✗ |
IKJ=(JK-1)*NG1P1+1 |
321 |
|
✗ |
IKJPN=IKJ+NG1 |
322 |
|
✗ |
DO JKK=IKJ,IKJPN |
323 |
|
✗ |
DO JL = KIDIA,KFDIA |
324 |
|
✗ |
ZDPMG = ZDPM(JL,JKK) |
325 |
|
✗ |
ZDPMP0 = ZDPMG / 101325._JPRB |
326 |
|
✗ |
ZUPMG = ZUPM(JL,JKK) * ZDPMP0 |
327 |
|
✗ |
ZUPMCO2 = ( ZUPM(JL,JKK) + RVGCO2 ) * ZDPMP0 |
328 |
|
✗ |
ZUPMH2O = ( ZUPM(JL,JKK) + RVGH2O ) * ZDPMP0 |
329 |
|
✗ |
ZUPMO3 = ( ZUPM(JL,JKK) + RVGO3 ) * ZDPMP0 |
330 |
|
✗ |
ZDUC(JL,JKK) = ZDPMG |
331 |
|
✗ |
ZABLY(JL,6,JKK) = ZXOZ(JL) * ZDPMG |
332 |
|
✗ |
ZABLY(JL,7,JKK) = ZXOZ(JL) * ZUPMO3 |
333 |
|
✗ |
ZU6 = ZXWV(JL) * ZUPMG |
334 |
|
✗ |
ZFPPW = 1.6078_JPRB * ZXWV(JL) / (1.0_JPRB+0.608_JPRB*ZXWV(JL)) |
335 |
|
✗ |
ZABLY(JL,1,JKK) = ZXWV(JL) * ZUPMH2O |
336 |
|
✗ |
ZABLY(JL,5,JKK) = ZU6 * ZFPPW |
337 |
|
✗ |
ZABLY(JL,4,JKK) = ZU6 * (1.0_JPRB-ZFPPW) |
338 |
|
✗ |
ZABLY(JL,3,JKK) = PCCO2 * ZUPMCO2 |
339 |
|
✗ |
ZABLY(JL,2,JKK) = PCCO2 * ZDPMG |
340 |
|
|
ENDDO |
341 |
|
|
ENDDO |
342 |
|
|
ENDDO |
343 |
|
|
|
344 |
|
|
!----------------------------------------------------------------------- |
345 |
|
|
|
346 |
|
|
!* 5. CUMULATIVE ABSORBER AMOUNTS FROM TOP OF ATMOSPHERE |
347 |
|
|
! -------------------------------------------------- |
348 |
|
|
|
349 |
|
✗ |
DO JA = 1, NUA |
350 |
|
✗ |
DO JL = KIDIA,KFDIA |
351 |
|
✗ |
PABCU(JL,JA,3*KLEV+1) = 0.0_JPRB |
352 |
|
|
ENDDO |
353 |
|
|
ENDDO |
354 |
|
|
|
355 |
|
✗ |
DO JK = 1 , KLEV |
356 |
|
✗ |
IJ=(JK-1)*NG1P1+1 |
357 |
|
✗ |
IJPN=IJ+NG1 |
358 |
|
✗ |
IKL=KLEV+1-JK |
359 |
|
|
|
360 |
|
|
!* 5.1 CUMULATIVE AEROSOL AMOUNTS FROM TOP OF ATMOSPHERE |
361 |
|
|
! -------------------------------------------------- |
362 |
|
|
! -- NB: 'PAER' AEROSOLS ARE ENTERED FROM TOP TO BOTTOM |
363 |
|
|
|
364 |
|
✗ |
IAE1=3*KLEV+1-IJ |
365 |
|
✗ |
IAE2=3*KLEV+1-(IJ+1) |
366 |
|
✗ |
IAE3=3*KLEV+1-IJPN |
367 |
|
|
! print *,'IAE1= ',IAE1 |
368 |
|
|
! print *,'IAE2= ',IAE2 |
369 |
|
|
! print *,'IAE3= ',IAE3 |
370 |
|
|
! print *,'KIDIA= ',KIDIA |
371 |
|
|
! print *,'KFDIA= ',KFDIA |
372 |
|
|
! print *,'KLEV= ',KLEV |
373 |
|
✗ |
DO JAE=1,6 |
374 |
|
✗ |
DO JL = KIDIA,KFDIA |
375 |
|
|
! print *,'JL= ',JL,'-JAE= ',JAE,'-JK= ',JK,'-NSIL= ',NSIL |
376 |
|
|
ZUAER(JL,JAE) =& |
377 |
|
|
& (RAER(JAE,1)*PAER(JL,1,JK)+RAER(JAE,2)*PAER(JL,2,JK)& |
378 |
|
|
& +RAER(JAE,3)*PAER(JL,3,JK)+RAER(JAE,4)*PAER(JL,4,JK)& |
379 |
|
|
& +RAER(JAE,5)*PAER(JL,5,JK)+RAER(JAE,6)*PAER(JL,6,JK))& |
380 |
|
✗ |
& /(ZDUC(JL,IAE1)+ZDUC(JL,IAE2)+ZDUC(JL,IAE3)) |
381 |
|
|
ENDDO |
382 |
|
|
ENDDO |
383 |
|
|
|
384 |
|
|
!* 5.2 INTRODUCES TEMPERATURE EFFECTS ON ABSORBER AMOUNTS |
385 |
|
|
! -------------------------------------------------- |
386 |
|
|
|
387 |
|
✗ |
DO JL = KIDIA,KFDIA |
388 |
|
✗ |
ZTAVI(JL)=PTAVE(JL,IKL) |
389 |
|
✗ |
ZFACT(JL)=1.0_JPRB-ZTAVI(JL)/296._JPRB |
390 |
|
✗ |
ZTCON(JL)=EXP(6.08_JPRB*(296._JPRB/ZTAVI(JL)-1.0_JPRB)) |
391 |
|
|
! ZTCON(JL)=EXP(6.08*ZFACT(JL)) |
392 |
|
✗ |
ZTX=ZTAVI(JL)-TREF |
393 |
|
✗ |
ZTX2=ZTX*ZTX |
394 |
|
✗ |
ZZABLY = ZABLY(JL,1,IAE1)+ZABLY(JL,1,IAE2)+ZABLY(JL,1,IAE3) |
395 |
|
✗ |
ZUP=MIN( MAX( 0.5_JPRB*R10E*LOG( ZZABLY ) + 5._JPRB, 0.0_JPRB), 6.0_JPRB) |
396 |
|
✗ |
ZCAH1=ALWT(1,1)+ZUP*(ALWT(1,2)+ZUP*(ALWT(1,3))) |
397 |
|
✗ |
ZCBH1=BLWT(1,1)+ZUP*(BLWT(1,2)+ZUP*(BLWT(1,3))) |
398 |
|
✗ |
ZPSH1(JL)=EXP( ZCAH1 * ZTX + ZCBH1 * ZTX2 ) |
399 |
|
✗ |
ZCAH2=ALWT(2,1)+ZUP*(ALWT(2,2)+ZUP*(ALWT(2,3))) |
400 |
|
✗ |
ZCBH2=BLWT(2,1)+ZUP*(BLWT(2,2)+ZUP*(BLWT(2,3))) |
401 |
|
✗ |
ZPSH2(JL)=EXP( ZCAH2 * ZTX + ZCBH2 * ZTX2 ) |
402 |
|
✗ |
ZCAH3=ALWT(3,1)+ZUP*(ALWT(3,2)+ZUP*(ALWT(3,3))) |
403 |
|
✗ |
ZCBH3=BLWT(3,1)+ZUP*(BLWT(3,2)+ZUP*(BLWT(3,3))) |
404 |
|
✗ |
ZPSH3(JL)=EXP( ZCAH3 * ZTX + ZCBH3 * ZTX2 ) |
405 |
|
✗ |
ZCAH4=ALWT(4,1)+ZUP*(ALWT(4,2)+ZUP*(ALWT(4,3))) |
406 |
|
✗ |
ZCBH4=BLWT(4,1)+ZUP*(BLWT(4,2)+ZUP*(BLWT(4,3))) |
407 |
|
✗ |
ZPSH4(JL)=EXP( ZCAH4 * ZTX + ZCBH4 * ZTX2 ) |
408 |
|
✗ |
ZCAH5=ALWT(5,1)+ZUP*(ALWT(5,2)+ZUP*(ALWT(5,3))) |
409 |
|
✗ |
ZCBH5=BLWT(5,1)+ZUP*(BLWT(5,2)+ZUP*(BLWT(5,3))) |
410 |
|
✗ |
ZPSH5(JL)=EXP( ZCAH5 * ZTX + ZCBH5 * ZTX2 ) |
411 |
|
✗ |
ZCAH6=ALWT(6,1)+ZUP*(ALWT(6,2)+ZUP*(ALWT(6,3))) |
412 |
|
✗ |
ZCBH6=BLWT(6,1)+ZUP*(BLWT(6,2)+ZUP*(BLWT(6,3))) |
413 |
|
✗ |
ZPSH6(JL)=EXP( ZCAH6 * ZTX + ZCBH6 * ZTX2 ) |
414 |
|
✗ |
ZPHM6(JL)=EXP(-5.81E-4_JPRB * ZTX - 1.13E-6_JPRB * ZTX2 ) |
415 |
|
✗ |
ZPSM6(JL)=EXP(-5.57E-4_JPRB * ZTX - 3.30E-6_JPRB * ZTX2 ) |
416 |
|
✗ |
ZPHN6(JL)=EXP(-3.46E-5_JPRB * ZTX + 2.05E-7_JPRB * ZTX2 ) |
417 |
|
✗ |
ZPSN6(JL)=EXP( 3.70E-3_JPRB * ZTX - 2.30E-6_JPRB * ZTX2 ) |
418 |
|
|
ENDDO |
419 |
|
|
|
420 |
|
✗ |
DO JL = KIDIA,KFDIA |
421 |
|
✗ |
ZTAVI(JL)=PTAVE(JL,IKL) |
422 |
|
✗ |
ZTX=ZTAVI(JL)-TREF |
423 |
|
✗ |
ZTX2=ZTX*ZTX |
424 |
|
✗ |
ZZABLY = ZABLY(JL,3,IAE1)+ZABLY(JL,3,IAE2)+ZABLY(JL,3,IAE3) |
425 |
|
✗ |
ZALUP = R10E * LOG ( ZZABLY ) |
426 |
|
✗ |
ZUP = MAX( 0.0_JPRB , 5.0_JPRB + 0.5_JPRB * ZALUP ) |
427 |
|
✗ |
ZPSC2(JL) = (ZTAVI(JL)/TREF) ** ZUP |
428 |
|
✗ |
ZCAC8=ALWT(8,1)+ZUP*(ALWT(8,2)+ZUP*(ALWT(8,3))) |
429 |
|
✗ |
ZCBC8=BLWT(8,1)+ZUP*(BLWT(8,2)+ZUP*(BLWT(8,3))) |
430 |
|
✗ |
ZPSC3(JL)=EXP( ZCAC8 * ZTX + ZCBC8 * ZTX2 ) |
431 |
|
✗ |
ZPHIO(JL) = EXP( RO3T(1) * ZTX + RO3T(2) * ZTX2) |
432 |
|
✗ |
ZPSIO(JL) = EXP( 2.0_JPRB* (RO3T(3)*ZTX+RO3T(4)*ZTX2)) |
433 |
|
|
ENDDO |
434 |
|
|
|
435 |
|
✗ |
DO JKK=IJ,IJPN |
436 |
|
✗ |
IC=3*KLEV+1-JKK |
437 |
|
✗ |
ICP1=IC+1 |
438 |
|
✗ |
DO JL = KIDIA,KFDIA |
439 |
|
✗ |
ZDIFF = PVIEW(JL) |
440 |
|
|
!- H2O continuum |
441 |
|
✗ |
PABCU(JL,10,IC)=PABCU(JL,10,ICP1)+ ZABLY(JL,4,IC) *ZDIFF |
442 |
|
✗ |
PABCU(JL,11,IC)=PABCU(JL,11,ICP1)+ ZABLY(JL,5,IC)*ZTCON(JL)*ZDIFF |
443 |
|
|
!- O3 |
444 |
|
✗ |
PABCU(JL,12,IC)=PABCU(JL,12,ICP1)+ ZABLY(JL,6,IC)*ZPHIO(JL)*ZDIFF |
445 |
|
✗ |
PABCU(JL,13,IC)=PABCU(JL,13,ICP1)+ ZABLY(JL,7,IC)*ZPSIO(JL)*ZDIFF |
446 |
|
|
!- CO2 |
447 |
|
✗ |
PABCU(JL,7,IC)=PABCU(JL,7,ICP1)+ ZABLY(JL,3,IC)*ZPSC2(JL)*ZDIFF |
448 |
|
✗ |
PABCU(JL,8,IC)=PABCU(JL,8,ICP1)+ ZABLY(JL,3,IC)*ZPSC3(JL)*ZDIFF |
449 |
|
✗ |
PABCU(JL,9,IC)=PABCU(JL,9,ICP1)+ ZABLY(JL,3,IC)*ZPSC3(JL)*ZDIFF |
450 |
|
|
!- H2O |
451 |
|
✗ |
PABCU(JL,1,IC)=PABCU(JL,1,ICP1)+ ZABLY(JL,1,IC)*ZPSH1(JL) |
452 |
|
✗ |
PABCU(JL,2,IC)=PABCU(JL,2,ICP1)+ ZABLY(JL,1,IC)*ZPSH2(JL) |
453 |
|
✗ |
PABCU(JL,3,IC)=PABCU(JL,3,ICP1)+ ZABLY(JL,1,IC)*ZPSH5(JL)*ZDIFF |
454 |
|
✗ |
PABCU(JL,4,IC)=PABCU(JL,4,ICP1)+ ZABLY(JL,1,IC)*ZPSH3(JL) |
455 |
|
✗ |
PABCU(JL,5,IC)=PABCU(JL,5,ICP1)+ ZABLY(JL,1,IC)*ZPSH4(JL) |
456 |
|
✗ |
PABCU(JL,6,IC)=PABCU(JL,6,ICP1)+ ZABLY(JL,1,IC)*ZPSH6(JL)*ZDIFF |
457 |
|
|
!- aerosols |
458 |
|
✗ |
PABCU(JL,14,IC)=PABCU(JL,14,ICP1)+ ZUAER(JL,1) *ZDUC(JL,IC)*ZDIFF |
459 |
|
✗ |
PABCU(JL,15,IC)=PABCU(JL,15,ICP1)+ ZUAER(JL,2) *ZDUC(JL,IC)*ZDIFF |
460 |
|
✗ |
PABCU(JL,16,IC)=PABCU(JL,16,ICP1)+ ZUAER(JL,3) *ZDUC(JL,IC)*ZDIFF |
461 |
|
✗ |
PABCU(JL,17,IC)=PABCU(JL,17,ICP1)+ ZUAER(JL,4) *ZDUC(JL,IC)*ZDIFF |
462 |
|
✗ |
PABCU(JL,18,IC)=PABCU(JL,18,ICP1)+ ZUAER(JL,5) *ZDUC(JL,IC)*ZDIFF |
463 |
|
|
!- CH4 |
464 |
|
|
PABCU(JL,19,IC)=PABCU(JL,19,ICP1)& |
465 |
|
✗ |
& + ZABLY(JL,2,IC)*RCH4/PCCO2*ZPHM6(JL)*ZDIFF |
466 |
|
|
PABCU(JL,20,IC)=PABCU(JL,20,ICP1)& |
467 |
|
✗ |
& + ZABLY(JL,3,IC)*RCH4/PCCO2*ZPSM6(JL)*ZDIFF |
468 |
|
|
!- N2O |
469 |
|
|
PABCU(JL,21,IC)=PABCU(JL,21,ICP1)& |
470 |
|
✗ |
& + ZABLY(JL,2,IC)*RN2O/PCCO2*ZPHN6(JL)*ZDIFF |
471 |
|
|
PABCU(JL,22,IC)=PABCU(JL,22,ICP1)& |
472 |
|
✗ |
& + ZABLY(JL,3,IC)*RN2O/PCCO2*ZPSN6(JL)*ZDIFF |
473 |
|
|
!- CFC11 |
474 |
|
|
PABCU(JL,23,IC)=PABCU(JL,23,ICP1)& |
475 |
|
✗ |
& + ZABLY(JL,2,IC)*RCFC11/PCCO2 *ZDIFF |
476 |
|
|
!- CFC12 |
477 |
|
|
PABCU(JL,24,IC)=PABCU(JL,24,ICP1)& |
478 |
|
✗ |
& + ZABLY(JL,2,IC)*RCFC12/PCCO2 *ZDIFF |
479 |
|
|
ENDDO |
480 |
|
|
ENDDO |
481 |
|
|
|
482 |
|
|
ENDDO |
483 |
|
|
! print *,'END OF LWU' |
484 |
|
|
|
485 |
|
|
|
486 |
|
|
|
487 |
|
|
!----------------------------------------------------------------------- |
488 |
|
|
|
489 |
|
✗ |
IF (LHOOK) CALL DR_HOOK('LWU',1,ZHOOK_HANDLE) |
490 |
|
✗ |
END SUBROUTINE LWU |
491 |
|
|
|