--- trunk/libf/phylmd/physiq.f90 2012/01/10 19:02:02 56 +++ trunk/Sources/phylmd/physiq.f 2015/07/08 17:03:45 155 @@ -4,46 +4,50 @@ contains - SUBROUTINE physiq(lafin, rdayvrai, time, dtphys, paprs, play, pphi, pphis, & - u, v, t, qx, omega, d_u, d_v, d_t, d_qx, d_ps, dudyn, PVteta) + SUBROUTINE physiq(lafin, dayvrai, time, paprs, play, pphi, pphis, u, v, t, & + qx, omega, d_u, d_v, d_t, d_qx) - ! From phylmd/physiq.F, version 1.22 2006/02/20 09:38:28 (SVN revision 678) - ! Author: Z.X. Li (LMD/CNRS) 1993 + ! From phylmd/physiq.F, version 1.22 2006/02/20 09:38:28 + ! (subversion revision 678) + + ! Author: Z. X. Li (LMD/CNRS) 1993 ! This is the main procedure for the "physics" part of the program. use aaam_bud_m, only: aaam_bud USE abort_gcm_m, ONLY: abort_gcm + use aeropt_m, only: aeropt use ajsec_m, only: ajsec - USE calendar, ONLY: ymds2ju use calltherm_m, only: calltherm USE clesphys, ONLY: cdhmax, cdmmax, co2_ppm, ecrit_hf, ecrit_ins, & ecrit_mth, ecrit_reg, ecrit_tra, ksta, ksta_ter, ok_kzmin USE clesphys2, ONLY: cycle_diurne, iflag_con, nbapp_rad, new_oliq, & - ok_orodr, ok_orolf, soil_model + ok_orodr, ok_orolf USE clmain_m, ONLY: clmain - USE comgeomphy, ONLY: airephy, cuphy, cvphy + use clouds_gno_m, only: clouds_gno + use comconst, only: dtphys + USE comgeomphy, ONLY: airephy USE concvl_m, ONLY: concvl - USE conf_gcm_m, ONLY: offline, raz_date + USE conf_gcm_m, ONLY: offline, raz_date, day_step, iphysiq USE conf_phys_m, ONLY: conf_phys + use conflx_m, only: conflx USE ctherm, ONLY: iflag_thermals, nsplit_thermals use diagcld2_m, only: diagcld2 use diagetpq_m, only: diagetpq - USE dimens_m, ONLY: iim, jjm, llm, nqmx - USE dimphy, ONLY: klon, nbtr + use diagphy_m, only: diagphy + USE dimens_m, ONLY: llm, nqmx + USE dimphy, ONLY: klon USE dimsoil, ONLY: nsoilmx use drag_noro_m, only: drag_noro + use dynetat0_m, only: day_ref, annee_ref USE fcttre, ONLY: foeew, qsatl, qsats, thermcep + use fisrtilp_m, only: fisrtilp USE hgardfou_m, ONLY: hgardfou - USE histcom, ONLY: histsync - USE histwrite_m, ONLY: histwrite USE indicesol, ONLY: clnsurf, epsfra, is_lic, is_oce, is_sic, is_ter, & nbsrf - USE ini_histhf_m, ONLY: ini_histhf - USE ini_histday_m, ONLY: ini_histday USE ini_histins_m, ONLY: ini_histins - USE oasis_m, ONLY: ok_oasis - USE orbite_m, ONLY: orbite, zenang + use newmicro_m, only: newmicro + USE orbite_m, ONLY: orbite USE ozonecm_m, ONLY: ozonecm USE phyetat0_m, ONLY: phyetat0, rlat, rlon USE phyredem_m, ONLY: phyredem @@ -51,91 +55,73 @@ USE phytrac_m, ONLY: phytrac USE qcheck_m, ONLY: qcheck use radlwsw_m, only: radlwsw + use readsulfate_m, only: readsulfate + use readsulfate_preind_m, only: readsulfate_preind use sugwd_m, only: sugwd USE suphec_m, ONLY: ra, rcpd, retv, rg, rlvtt, romega, rsigma, rtt - USE temps, ONLY: annee_ref, day_ref, itau_phy + USE temps, ONLY: itau_phy + use unit_nml_m, only: unit_nml + USE ymds2ju_m, ONLY: ymds2ju USE yoethf_m, ONLY: r2es, rvtmp2 + use zenang_m, only: zenang - ! Arguments: + logical, intent(in):: lafin ! dernier passage - REAL, intent(in):: rdayvrai - ! (elapsed time since January 1st 0h of the starting year, in days) + integer, intent(in):: dayvrai + ! current day number, based at value 1 on January 1st of annee_ref - REAL, intent(in):: time ! heure de la journée en fraction de jour - REAL, intent(in):: dtphys ! pas d'integration pour la physique (seconde) - logical, intent(in):: lafin ! dernier passage + REAL, intent(in):: time ! heure de la journ\'ee en fraction de jour - REAL, intent(in):: paprs(klon, llm + 1) - ! (pression pour chaque inter-couche, en Pa) + REAL, intent(in):: paprs(:, :) ! (klon, llm + 1) + ! pression pour chaque inter-couche, en Pa - REAL, intent(in):: play(klon, llm) - ! (input pression pour le mileu de chaque couche (en Pa)) + REAL, intent(in):: play(:, :) ! (klon, llm) + ! pression pour le mileu de chaque couche (en Pa) - REAL, intent(in):: pphi(klon, llm) - ! (input geopotentiel de chaque couche (g z) (reference sol)) + REAL, intent(in):: pphi(:, :) ! (klon, llm) + ! géopotentiel de chaque couche (référence sol) - REAL, intent(in):: pphis(klon) ! input geopotentiel du sol + REAL, intent(in):: pphis(:) ! (klon) géopotentiel du sol - REAL, intent(in):: u(klon, llm) + REAL, intent(in):: u(:, :) ! (klon, llm) ! vitesse dans la direction X (de O a E) en m/s - REAL, intent(in):: v(klon, llm) ! vitesse Y (de S a N) en m/s - REAL, intent(in):: t(klon, llm) ! input temperature (K) + REAL, intent(in):: v(:, :) ! (klon, llm) vitesse Y (de S a N) en m/s + REAL, intent(in):: t(:, :) ! (klon, llm) temperature (K) - REAL, intent(in):: qx(klon, llm, nqmx) - ! (humidité spécifique et fractions massiques des autres traceurs) + REAL, intent(in):: qx(:, :, :) ! (klon, llm, nqmx) + ! (humidit\'e sp\'ecifique et fractions massiques des autres traceurs) - REAL omega(klon, llm) ! input vitesse verticale en Pa/s - REAL, intent(out):: d_u(klon, llm) ! tendance physique de "u" (m/s/s) - REAL, intent(out):: d_v(klon, llm) ! tendance physique de "v" (m/s/s) - REAL, intent(out):: d_t(klon, llm) ! tendance physique de "t" (K/s) - REAL d_qx(klon, llm, nqmx) ! output tendance physique de "qx" (kg/kg/s) - REAL d_ps(klon) ! output tendance physique de la pression au sol + REAL, intent(in):: omega(:, :) ! (klon, llm) vitesse verticale en Pa/s + REAL, intent(out):: d_u(:, :) ! (klon, llm) tendance physique de "u" (m s-2) + REAL, intent(out):: d_v(:, :) ! (klon, llm) tendance physique de "v" (m s-2) + REAL, intent(out):: d_t(:, :) ! (klon, llm) tendance physique de "t" (K/s) - LOGICAL:: firstcal = .true. + REAL, intent(out):: d_qx(:, :, :) ! (klon, llm, nqmx) + ! tendance physique de "qx" (s-1) - INTEGER nbteta - PARAMETER(nbteta = 3) + ! Local: - REAL PVteta(klon, nbteta) - ! (output vorticite potentielle a des thetas constantes) + LOGICAL:: firstcal = .true. - LOGICAL ok_cvl ! pour activer le nouveau driver pour convection KE - PARAMETER (ok_cvl = .TRUE.) LOGICAL ok_gust ! pour activer l'effet des gust sur flux surface PARAMETER (ok_gust = .FALSE.) - LOGICAL check ! Verifier la conservation du modele en eau - PARAMETER (check = .FALSE.) + LOGICAL, PARAMETER:: check = .FALSE. + ! Verifier la conservation du modele en eau LOGICAL, PARAMETER:: ok_stratus = .FALSE. ! Ajouter artificiellement les stratus - ! Parametres lies au coupleur OASIS: - INTEGER, SAVE:: npas, nexca - logical rnpb - parameter(rnpb = .true.) - - character(len = 6), save:: ocean - ! (type de modèle océan à utiliser: "force" ou "slab" mais pas "couple") - - logical ok_ocean - SAVE ok_ocean - ! "slab" ocean REAL, save:: tslab(klon) ! temperature of ocean slab REAL, save:: seaice(klon) ! glace de mer (kg/m2) REAL fluxo(klon) ! flux turbulents ocean-glace de mer REAL fluxg(klon) ! flux turbulents ocean-atmosphere - ! Modele thermique du sol, a activer pour le cycle diurne: - logical, save:: ok_veget - LOGICAL, save:: ok_journe ! sortir le fichier journalier - - LOGICAL ok_mensuel ! sortir le fichier mensuel - - LOGICAL ok_instan ! sortir le fichier instantane - save ok_instan + logical:: ok_journe = .false., ok_mensuel = .true., ok_instan = .false. + ! sorties journalieres, mensuelles et instantanees dans les + ! fichiers histday, histmth et histins LOGICAL ok_region ! sortir le fichier regional PARAMETER (ok_region = .FALSE.) @@ -145,10 +131,8 @@ REAL entr_therm(klon, llm) real, save:: q2(klon, llm + 1, nbsrf) - INTEGER ivap ! indice de traceurs pour vapeur d'eau - PARAMETER (ivap = 1) - INTEGER iliq ! indice de traceurs pour eau liquide - PARAMETER (iliq = 2) + INTEGER, PARAMETER:: ivap = 1 ! indice de traceur pour vapeur d'eau + INTEGER, PARAMETER:: iliq = 2 ! indice de traceur pour eau liquide REAL, save:: t_ancien(klon, llm), q_ancien(klon, llm) LOGICAL, save:: ancien_ok @@ -158,27 +142,15 @@ real da(klon, llm), phi(klon, llm, llm), mp(klon, llm) - !IM Amip2 PV a theta constante - - CHARACTER(LEN = 3) ctetaSTD(nbteta) - DATA ctetaSTD/'350', '380', '405'/ - REAL rtetaSTD(nbteta) - DATA rtetaSTD/350., 380., 405./ - - !MI Amip2 PV a theta constante - - INTEGER klevp1 - PARAMETER(klevp1 = llm + 1) - - REAL swdn0(klon, klevp1), swdn(klon, klevp1) - REAL swup0(klon, klevp1), swup(klon, klevp1) + REAL swdn0(klon, llm + 1), swdn(klon, llm + 1) + REAL swup0(klon, llm + 1), swup(klon, llm + 1) SAVE swdn0, swdn, swup0, swup - REAL lwdn0(klon, klevp1), lwdn(klon, klevp1) - REAL lwup0(klon, klevp1), lwup(klon, klevp1) + REAL lwdn0(klon, llm + 1), lwdn(klon, llm + 1) + REAL lwup0(klon, llm + 1), lwup(klon, llm + 1) SAVE lwdn0, lwdn, lwup0, lwup - !IM Amip2 + ! Amip2 ! variables a une pression donnee integer nlevSTD @@ -206,7 +178,7 @@ PARAMETER(kmaxm1 = kmax-1, lmaxm1 = lmax-1) REAL zx_tau(kmaxm1), zx_pc(lmaxm1) - DATA zx_tau/0.0, 0.3, 1.3, 3.6, 9.4, 23., 60./ + DATA zx_tau/0., 0.3, 1.3, 3.6, 9.4, 23., 60./ DATA zx_pc/50., 180., 310., 440., 560., 680., 800./ ! cldtopres pression au sommet des nuages @@ -247,16 +219,13 @@ 'pc= 440-560hPa, tau> 60.', 'pc= 560-680hPa, tau> 60.', & 'pc= 680-800hPa, tau> 60.'/ - !IM ISCCP simulator v3.4 - - integer nid_hf, nid_hf3d - save nid_hf, nid_hf3d + ! ISCCP simulator v3.4 ! Variables propres a la physique INTEGER, save:: radpas - ! (Radiative transfer computations are made every "radpas" call to - ! "physiq".) + ! Radiative transfer computations are made every "radpas" call to + ! "physiq". REAL radsol(klon) SAVE radsol ! bilan radiatif au sol calcule par code radiatif @@ -268,25 +237,20 @@ REAL, save:: ftsoil(klon, nsoilmx, nbsrf) ! soil temperature of surface fraction - REAL fevap(klon, nbsrf) - SAVE fevap ! evaporation + REAL, save:: fevap(klon, nbsrf) ! evaporation REAL fluxlat(klon, nbsrf) SAVE fluxlat - REAL fqsurf(klon, nbsrf) - SAVE fqsurf ! humidite de l'air au contact de la surface + REAL, save:: fqsurf(klon, nbsrf) + ! humidite de l'air au contact de la surface - REAL, save:: qsol(klon) ! hauteur d'eau dans le sol + REAL, save:: qsol(klon) + ! column-density of water in soil, in kg m-2 - REAL fsnow(klon, nbsrf) - SAVE fsnow ! epaisseur neigeuse + REAL, save:: fsnow(klon, nbsrf) ! epaisseur neigeuse + REAL, save:: falbe(klon, nbsrf) ! albedo visible par type de surface - REAL falbe(klon, nbsrf) - SAVE falbe ! albedo par type de surface - REAL falblw(klon, nbsrf) - SAVE falblw ! albedo par type de surface - - ! Paramètres de l'orographie à l'échelle sous-maille (OESM) : + ! Param\`etres de l'orographie \`a l'\'echelle sous-maille (OESM) : REAL, save:: zmea(klon) ! orographie moyenne REAL, save:: zstd(klon) ! deviation standard de l'OESM REAL, save:: zsig(klon) ! pente de l'OESM @@ -308,19 +272,12 @@ !KE43 ! Variables liees a la convection de K. Emanuel (sb): - REAL bas, top ! cloud base and top levels - SAVE bas - SAVE top - REAL Ma(klon, llm) ! undilute upward mass flux SAVE Ma REAL qcondc(klon, llm) ! in-cld water content from convect SAVE qcondc - REAL ema_work1(klon, llm), ema_work2(klon, llm) - SAVE ema_work1, ema_work2 - - REAL wd(klon) ! sb - SAVE wd ! sb + REAL, save:: sig1(klon, llm), w01(klon, llm) + REAL, save:: wd(klon) ! Variables locales pour la couche limite (al1): @@ -329,7 +286,7 @@ REAL cdragh(klon) ! drag coefficient pour T and Q REAL cdragm(klon) ! drag coefficient pour vent - !AA Pour phytrac + ! Pour phytrac : REAL ycoefh(klon, llm) ! coef d'echange pour phytrac REAL yu1(klon) ! vents dans la premiere couche U REAL yv1(klon) ! vents dans la premiere couche V @@ -348,61 +305,46 @@ REAL frac_impa(klon, llm) ! fractions d'aerosols lessivees (impaction) REAL frac_nucl(klon, llm) ! idem (nucleation) - !AA - REAL rain_fall(klon) ! pluie - REAL snow_fall(klon) ! neige - save snow_fall, rain_fall - !IM cf FH pour Tiedtke 080604 + REAL, save:: rain_fall(klon) + ! liquid water mass flux (kg/m2/s), positive down + + REAL, save:: snow_fall(klon) + ! solid water mass flux (kg/m2/s), positive down + REAL rain_tiedtke(klon), snow_tiedtke(klon) - REAL evap(klon), devap(klon) ! evaporation et sa derivee + REAL evap(klon), devap(klon) ! evaporation and its derivative REAL sens(klon), dsens(klon) ! chaleur sensible et sa derivee REAL dlw(klon) ! derivee infra rouge SAVE dlw REAL bils(klon) ! bilan de chaleur au sol - REAL fder(klon) ! Derive de flux (sensible et latente) - save fder + REAL, save:: fder(klon) ! Derive de flux (sensible et latente) REAL ve(klon) ! integr. verticale du transport meri. de l'energie REAL vq(klon) ! integr. verticale du transport meri. de l'eau REAL ue(klon) ! integr. verticale du transport zonal de l'energie REAL uq(klon) ! integr. verticale du transport zonal de l'eau - REAL frugs(klon, nbsrf) ! longueur de rugosite - save frugs + REAL, save:: frugs(klon, nbsrf) ! longueur de rugosite REAL zxrugs(klon) ! longueur de rugosite ! Conditions aux limites INTEGER julien - INTEGER, SAVE:: lmt_pas ! number of time steps of "physics" per day - REAL pctsrf(klon, nbsrf) - !IM - REAL pctsrf_new(klon, nbsrf) !pourcentage surfaces issus d'ORCHIDEE - - SAVE pctsrf ! sous-fraction du sol - REAL albsol(klon) - SAVE albsol ! albedo du sol total - REAL albsollw(klon) - SAVE albsollw ! albedo du sol total - + REAL, save:: pctsrf(klon, nbsrf) ! percentage of surface + REAL pctsrf_new(klon, nbsrf) ! pourcentage surfaces issus d'ORCHIDEE + REAL, save:: albsol(klon) ! albedo du sol total visible REAL, SAVE:: wo(klon, llm) ! column density of ozone in a cell, in kDU ! Declaration des procedures appelees - EXTERNAL alboc ! calculer l'albedo sur ocean - !KE43 - EXTERNAL conema3 ! convect4.3 - EXTERNAL fisrtilp ! schema de condensation a grande echelle (pluie) EXTERNAL nuage ! calculer les proprietes radiatives EXTERNAL transp ! transport total de l'eau et de l'energie ! Variables locales - real clwcon(klon, llm), rnebcon(klon, llm) - real clwcon0(klon, llm), rnebcon0(klon, llm) - - save rnebcon, clwcon + real, save:: clwcon(klon, llm), rnebcon(klon, llm) + real, save:: clwcon0(klon, llm), rnebcon0(klon, llm) REAL rhcl(klon, llm) ! humiditi relative ciel clair REAL dialiq(klon, llm) ! eau liquide nuageuse @@ -422,23 +364,19 @@ REAL zxfluxu(klon, llm) REAL zxfluxv(klon, llm) - ! Le rayonnement n'est pas calcule tous les pas, il faut donc - ! que les variables soient rémanentes + ! Le rayonnement n'est pas calcul\'e tous les pas, il faut donc que + ! les variables soient r\'emanentes. REAL, save:: heat(klon, llm) ! chauffage solaire - REAL heat0(klon, llm) ! chauffage solaire ciel clair - REAL cool(klon, llm) ! refroidissement infrarouge - REAL cool0(klon, llm) ! refroidissement infrarouge ciel clair - REAL topsw(klon), toplw(klon), solsw(klon), sollw(klon) - real sollwdown(klon) ! downward LW flux at surface - REAL topsw0(klon), toplw0(klon), solsw0(klon), sollw0(klon) - REAL albpla(klon) + REAL, save:: heat0(klon, llm) ! chauffage solaire ciel clair + REAL, save:: cool(klon, llm) ! refroidissement infrarouge + REAL, save:: cool0(klon, llm) ! refroidissement infrarouge ciel clair + REAL, save:: topsw(klon), toplw(klon), solsw(klon) + REAL, save:: sollw(klon) ! rayonnement infrarouge montant \`a la surface + real, save:: sollwdown(klon) ! downward LW flux at surface + REAL, save:: topsw0(klon), toplw0(klon), solsw0(klon), sollw0(klon) + REAL, save:: albpla(klon) REAL fsollw(klon, nbsrf) ! bilan flux IR pour chaque sous surface REAL fsolsw(klon, nbsrf) ! flux solaire absorb. pour chaque sous surface - SAVE cool, albpla, topsw, toplw, solsw, sollw, sollwdown - SAVE topsw0, toplw0, solsw0, sollw0, heat0, cool0 - - INTEGER itaprad - SAVE itaprad REAL conv_q(klon, llm) ! convergence de l'humidite (kg/kg/s) REAL conv_t(klon, llm) ! convergence of temperature (K/s) @@ -448,23 +386,17 @@ REAL zxtsol(klon), zxqsurf(klon), zxsnow(klon), zxfluxlat(klon) - REAL dist, rmu0(klon), fract(klon) - REAL zdtime ! pas de temps du rayonnement (s) - real zlongi - + REAL dist, mu0(klon), fract(klon) + real longi REAL z_avant(klon), z_apres(klon), z_factor(klon) - LOGICAL zx_ajustq - REAL za, zb - REAL zx_t, zx_qs, zdelta, zcor + REAL zx_t, zx_qs, zcor real zqsat(klon, llm) INTEGER i, k, iq, nsrf - REAL t_coup - PARAMETER (t_coup = 234.0) - + REAL, PARAMETER:: t_coup = 234. REAL zphi(klon, llm) - !IM cf. AM Variables locales pour la CLA (hbtm2) + ! cf. AM Variables locales pour la CLA (hbtm2) REAL, SAVE:: pblh(klon, nbsrf) ! Hauteur de couche limite REAL, SAVE:: plcl(klon, nbsrf) ! Niveau de condensation de la CLA @@ -482,32 +414,22 @@ REAL s_therm(klon), s_trmb1(klon), s_trmb2(klon) REAL s_trmb3(klon) - ! Variables locales pour la convection de K. Emanuel (sb): + ! Variables locales pour la convection de K. Emanuel : REAL upwd(klon, llm) ! saturated updraft mass flux REAL dnwd(klon, llm) ! saturated downdraft mass flux REAL dnwd0(klon, llm) ! unsaturated downdraft mass flux - REAL tvp(klon, llm) ! virtual temp of lifted parcel REAL cape(klon) ! CAPE SAVE cape - REAL pbase(klon) ! cloud base pressure - SAVE pbase - REAL bbase(klon) ! cloud base buoyancy - SAVE bbase - REAL rflag(klon) ! flag fonctionnement de convect INTEGER iflagctrl(klon) ! flag fonctionnement de convect - ! -- convect43: - INTEGER ntra ! nb traceurs pour convect4.3 - REAL dtvpdt1(klon, llm), dtvpdq1(klon, llm) - REAL dplcldt(klon), dplcldr(klon) ! Variables du changement ! con: convection ! lsc: large scale condensation ! ajs: ajustement sec - ! eva: évaporation de l'eau liquide nuageuse + ! eva: \'evaporation de l'eau liquide nuageuse ! vdf: vertical diffusion in boundary layer REAL d_t_con(klon, llm), d_q_con(klon, llm) REAL d_u_con(klon, llm), d_v_con(klon, llm) @@ -516,14 +438,14 @@ REAL d_u_ajs(klon, llm), d_v_ajs(klon, llm) REAL rneb(klon, llm) - REAL pmfu(klon, llm), pmfd(klon, llm) + REAL mfu(klon, llm), mfd(klon, llm) REAL pen_u(klon, llm), pen_d(klon, llm) REAL pde_u(klon, llm), pde_d(klon, llm) INTEGER kcbot(klon), kctop(klon), kdtop(klon) REAL pmflxr(klon, llm + 1), pmflxs(klon, llm + 1) REAL prfl(klon, llm + 1), psfl(klon, llm + 1) - INTEGER,save:: ibas_con(klon), itop_con(klon) + INTEGER, save:: ibas_con(klon), itop_con(klon) REAL rain_con(klon), rain_lsc(klon) REAL snow_con(klon), snow_lsc(klon) @@ -537,30 +459,25 @@ REAL d_u_lif(klon, llm), d_v_lif(klon, llm) REAL d_t_lif(klon, llm) - REAL ratqs(klon, llm), ratqss(klon, llm), ratqsc(klon, llm) - real ratqsbas, ratqshaut - save ratqsbas, ratqshaut, ratqs + REAL, save:: ratqs(klon, llm) + real ratqss(klon, llm), ratqsc(klon, llm) + real:: ratqsbas = 0.01, ratqshaut = 0.3 ! Parametres lies au nouveau schema de nuages (SB, PDF) - real, save:: fact_cldcon - real, save:: facttemps - logical ok_newmicro - save ok_newmicro + real:: fact_cldcon = 0.375 + real:: facttemps = 1.e-4 + logical:: ok_newmicro = .true. real facteur - integer iflag_cldcon - save iflag_cldcon - + integer:: iflag_cldcon = 1 logical ptconv(klon, llm) - ! Variables locales pour effectuer les appels en série : + ! Variables locales pour effectuer les appels en s\'erie : REAL t_seri(klon, llm), q_seri(klon, llm) - REAL ql_seri(klon, llm), qs_seri(klon, llm) + REAL ql_seri(klon, llm) REAL u_seri(klon, llm), v_seri(klon, llm) - - REAL tr_seri(klon, llm, nbtr) - REAL d_tr(klon, llm, nbtr) + REAL tr_seri(klon, llm, nqmx - 2) REAL zx_rh(klon, llm) @@ -569,82 +486,70 @@ REAL zustrph(klon), zvstrph(klon) REAL aam, torsfc - REAL dudyn(iim + 1, jjm + 1, llm) - REAL zx_tmp_fi2d(klon) ! variable temporaire grille physique - REAL zx_tmp_2d(iim, jjm + 1), zx_tmp_3d(iim, jjm + 1, llm) - INTEGER, SAVE:: nid_day, nid_ins + INTEGER, SAVE:: nid_ins REAL ve_lay(klon, llm) ! transport meri. de l'energie a chaque niveau vert. REAL vq_lay(klon, llm) ! transport meri. de l'eau a chaque niveau vert. REAL ue_lay(klon, llm) ! transport zonal de l'energie a chaque niveau vert. REAL uq_lay(klon, llm) ! transport zonal de l'eau a chaque niveau vert. - REAL zsto - - character(len = 20) modname - character(len = 80) abort_message - logical ok_sync real date0 - ! Variables liées au bilan d'énergie et d'enthalpie : + ! Variables li\'ees au bilan d'\'energie et d'enthalpie : REAL ztsol(klon) - REAL d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec + REAL d_h_vcol, d_qt, d_ec REAL, SAVE:: d_h_vcol_phy - REAL fs_bound, fq_bound REAL zero_v(klon) - CHARACTER(LEN = 15) ztit + CHARACTER(LEN = 20) tit INTEGER:: ip_ebil = 0 ! print level for energy conservation diagnostics - INTEGER, SAVE:: if_ebil ! level for energy conservation diagnostics + INTEGER:: if_ebil = 0 ! verbosity for diagnostics of energy conservation - REAL d_t_ec(klon, llm) ! tendance due à la conversion Ec -> E thermique + REAL d_t_ec(klon, llm) ! tendance due \`a la conversion Ec -> E thermique REAL ZRCPD REAL t2m(klon, nbsrf), q2m(klon, nbsrf) ! temperature and humidity at 2 m - REAL u10m(klon, nbsrf), v10m(klon, nbsrf) !vents a 10m - REAL zt2m(klon), zq2m(klon) !temp., hum. 2m moyenne s/ 1 maille - REAL zu10m(klon), zv10m(klon) !vents a 10m moyennes s/1 maille - !jq Aerosol effects (Johannes Quaas, 27/11/2003) - REAL sulfate(klon, llm) ! SO4 aerosol concentration [ug/m3] + REAL u10m(klon, nbsrf), v10m(klon, nbsrf) ! vents a 10 m + REAL zt2m(klon), zq2m(klon) ! temp., hum. 2 m moyenne s/ 1 maille + REAL zu10m(klon), zv10m(klon) ! vents a 10 m moyennes s/1 maille + + ! Aerosol effects: + + REAL sulfate(klon, llm) ! SO4 aerosol concentration (micro g/m3) REAL, save:: sulfate_pi(klon, llm) - ! (SO4 aerosol concentration, in ug/m3, pre-industrial value) + ! SO4 aerosol concentration, in micro g/m3, pre-industrial value REAL cldtaupi(klon, llm) - ! (Cloud optical thickness for pre-industrial (pi) aerosols) + ! cloud optical thickness for pre-industrial (pi) aerosols REAL re(klon, llm) ! Cloud droplet effective radius REAL fl(klon, llm) ! denominator of re ! Aerosol optical properties - REAL tau_ae(klon, llm, 2), piz_ae(klon, llm, 2) - REAL cg_ae(klon, llm, 2) - - REAL topswad(klon), solswad(klon) ! Aerosol direct effect. - ! ok_ade = True -ADE = topswad-topsw + REAL, save:: tau_ae(klon, llm, 2), piz_ae(klon, llm, 2) + REAL, save:: cg_ae(klon, llm, 2) - REAL topswai(klon), solswai(klon) ! Aerosol indirect effect. - ! ok_aie = True -> - ! ok_ade = True -AIE = topswai-topswad - ! ok_ade = F -AIE = topswai-topsw + REAL topswad(klon), solswad(klon) ! aerosol direct effect + REAL topswai(klon), solswai(klon) ! aerosol indirect effect REAL aerindex(klon) ! POLDER aerosol index - ! Parameters - LOGICAL ok_ade, ok_aie ! Apply aerosol (in)direct effects or not - REAL bl95_b0, bl95_b1 ! Parameter in Boucher and Lohmann (1995) + LOGICAL:: ok_ade = .false. ! apply aerosol direct effect + LOGICAL:: ok_aie = .false. ! apply aerosol indirect effect + + REAL:: bl95_b0 = 2., bl95_b1 = 0.2 + ! Parameters in equation (D) of Boucher and Lohmann (1995, Tellus + ! B). They link cloud droplet number concentration to aerosol mass + ! concentration. - SAVE ok_ade, ok_aie, bl95_b0, bl95_b1 SAVE u10m SAVE v10m SAVE t2m SAVE q2m SAVE ffonte SAVE fqcalving - SAVE piz_ae - SAVE tau_ae - SAVE cg_ae SAVE rain_con SAVE snow_con SAVE topswai @@ -653,27 +558,21 @@ SAVE solswad SAVE d_u_con SAVE d_v_con - SAVE rnebcon0 - SAVE clwcon0 real zmasse(klon, llm) ! (column-density of mass of air in a cell, in kg m-2) real, parameter:: dobson_u = 2.1415e-05 ! Dobson unit, in kg m-2 + namelist /physiq_nml/ ok_journe, ok_mensuel, ok_instan, fact_cldcon, & + facttemps, ok_newmicro, iflag_cldcon, ratqsbas, ratqshaut, if_ebil, & + ok_ade, ok_aie, bl95_b0, bl95_b1, iflag_thermals, nsplit_thermals + !---------------------------------------------------------------- - modname = 'physiq' - IF (if_ebil >= 1) THEN - DO i = 1, klon - zero_v(i) = 0. - END DO - END IF - ok_sync = .TRUE. - IF (nqmx < 2) THEN - abort_message = 'eaux vapeur et liquide sont indispensables' - CALL abort_gcm(modname, abort_message, 1) - ENDIF + IF (if_ebil >= 1) zero_v = 0. + IF (nqmx < 2) CALL abort_gcm('physiq', & + 'eaux vapeur et liquide sont indispensables', 1) test_firstcal: IF (firstcal) THEN ! initialiser @@ -686,21 +585,19 @@ piz_ae = 0. tau_ae = 0. cg_ae = 0. - rain_con(:) = 0. - snow_con(:) = 0. - bl95_b0 = 0. - bl95_b1 = 0. - topswai(:) = 0. - topswad(:) = 0. - solswai(:) = 0. - solswad(:) = 0. - - d_u_con = 0.0 - d_v_con = 0.0 - rnebcon0 = 0.0 - clwcon0 = 0.0 - rnebcon = 0.0 - clwcon = 0.0 + rain_con = 0. + snow_con = 0. + topswai = 0. + topswad = 0. + solswai = 0. + solswad = 0. + + d_u_con = 0. + d_v_con = 0. + rnebcon0 = 0. + clwcon0 = 0. + rnebcon = 0. + clwcon = 0. pblh =0. ! Hauteur de couche limite plcl =0. ! Niveau de condensation de la CLA @@ -715,65 +612,41 @@ IF (if_ebil >= 1) d_h_vcol_phy = 0. - ! appel a la lecture du run.def physique + iflag_thermals = 0 + nsplit_thermals = 1 + print *, "Enter namelist 'physiq_nml'." + read(unit=*, nml=physiq_nml) + write(unit_nml, nml=physiq_nml) - call conf_phys(ocean, ok_veget, ok_journe, ok_mensuel, & - ok_instan, fact_cldcon, facttemps, ok_newmicro, & - iflag_cldcon, ratqsbas, ratqshaut, if_ebil, & - ok_ade, ok_aie, & - bl95_b0, bl95_b1, & - iflag_thermals, nsplit_thermals) + call conf_phys ! Initialiser les compteurs: frugs = 0. itap = 0 - itaprad = 0 - CALL phyetat0("startphy.nc", pctsrf, ftsol, ftsoil, ocean, tslab, & - seaice, fqsurf, qsol, fsnow, falbe, falblw, fevap, rain_fall, & - snow_fall, solsw, sollwdown, dlw, radsol, frugs, agesno, zmea, & - zstd, zsig, zgam, zthe, zpic, zval, t_ancien, q_ancien, & - ancien_ok, rnebcon, ratqs, clwcon, run_off_lic_0) + CALL phyetat0(pctsrf, ftsol, ftsoil, tslab, seaice, fqsurf, qsol, & + fsnow, falbe, fevap, rain_fall, snow_fall, solsw, sollw, & + dlw, radsol, frugs, agesno, zmea, zstd, zsig, zgam, zthe, zpic, & + zval, t_ancien, q_ancien, ancien_ok, rnebcon, ratqs, clwcon, & + run_off_lic_0, sig1, w01) ! ATTENTION : il faudra a terme relire q2 dans l'etat initial - q2 = 1.e-8 - - radpas = NINT(86400. / dtphys / nbapp_rad) + q2 = 1e-8 - ! on remet le calendrier a zero - IF (raz_date) itau_phy = 0 + lmt_pas = day_step / iphysiq + print *, 'Number of time steps of "physics" per day: ', lmt_pas - PRINT *, 'cycle_diurne = ', cycle_diurne + radpas = lmt_pas / nbapp_rad - IF(ocean.NE.'force ') THEN - ok_ocean = .TRUE. - ENDIF - - CALL printflag(radpas, ok_ocean, ok_oasis, ok_journe, ok_instan, & - ok_region) + ! On remet le calendrier a zero + IF (raz_date) itau_phy = 0 - IF (dtphys*REAL(radpas) > 21600..AND.cycle_diurne) THEN - print *,'Nbre d appels au rayonnement insuffisant' - print *,"Au minimum 4 appels par jour si cycle diurne" - abort_message = 'Nbre d appels au rayonnement insuffisant' - call abort_gcm(modname, abort_message, 1) - ENDIF - print *,"Clef pour la convection, iflag_con = ", iflag_con - print *,"Clef pour le driver de la convection, ok_cvl = ", & - ok_cvl + CALL printflag(radpas, ok_journe, ok_instan, ok_region) - ! Initialisation pour la convection de K.E. (sb): + ! Initialisation pour le sch\'ema de convection d'Emanuel : IF (iflag_con >= 3) THEN - - print *,"*** Convection de Kerry Emanuel 4.3 " - - !IM15/11/02 rajout initialisation ibas_con, itop_con cf. SB =>BEG - DO i = 1, klon - ibas_con(i) = 1 - itop_con(i) = 1 - ENDDO - !IM15/11/02 rajout initialisation ibas_con, itop_con cf. SB =>END - + ibas_con = 1 + itop_con = 1 ENDIF IF (ok_orodr) THEN @@ -783,88 +656,43 @@ rugoro = 0. ENDIF - lmt_pas = NINT(86400. / dtphys) ! tous les jours - print *, 'Number of time steps of "physics" per day: ', lmt_pas - ecrit_ins = NINT(ecrit_ins/dtphys) ecrit_hf = NINT(ecrit_hf/dtphys) ecrit_mth = NINT(ecrit_mth/dtphys) ecrit_tra = NINT(86400.*ecrit_tra/dtphys) ecrit_reg = NINT(ecrit_reg/dtphys) - ! Initialiser le couplage si necessaire - - npas = 0 - nexca = 0 - - print *,'AVANT HIST IFLAG_CON = ', iflag_con - ! Initialisation des sorties - call ini_histhf(dtphys, nid_hf, nid_hf3d) - call ini_histday(dtphys, ok_journe, nid_day, nqmx) call ini_histins(dtphys, ok_instan, nid_ins) - CALL ymds2ju(annee_ref, 1, int(day_ref), 0., date0) - !XXXPB Positionner date0 pour initialisation de ORCHIDEE - WRITE(*, *) 'physiq date0: ', date0 + CALL ymds2ju(annee_ref, 1, day_ref, 0., date0) + ! Positionner date0 pour initialisation de ORCHIDEE + print *, 'physiq date0: ', date0 ENDIF test_firstcal - ! Mettre a zero des variables de sortie (pour securite) - - DO i = 1, klon - d_ps(i) = 0.0 - ENDDO - DO iq = 1, nqmx - DO k = 1, llm - DO i = 1, klon - d_qx(i, k, iq) = 0.0 - ENDDO - ENDDO - ENDDO - da = 0. - mp = 0. - phi = 0. + ! We will modify variables *_seri and we will not touch variables + ! u, v, t, qx: + t_seri = t + u_seri = u + v_seri = v + q_seri = qx(:, :, ivap) + ql_seri = qx(:, :, iliq) + tr_seri = qx(:, :, 3: nqmx) - ! Ne pas affecter les valeurs entrées de u, v, h, et q : - - DO k = 1, llm - DO i = 1, klon - t_seri(i, k) = t(i, k) - u_seri(i, k) = u(i, k) - v_seri(i, k) = v(i, k) - q_seri(i, k) = qx(i, k, ivap) - ql_seri(i, k) = qx(i, k, iliq) - qs_seri(i, k) = 0. - ENDDO - ENDDO - IF (nqmx >= 3) THEN - tr_seri(:, :, :nqmx-2) = qx(:, :, 3:nqmx) - ELSE - tr_seri(:, :, 1) = 0. - ENDIF - - DO i = 1, klon - ztsol(i) = 0. - ENDDO - DO nsrf = 1, nbsrf - DO i = 1, klon - ztsol(i) = ztsol(i) + ftsol(i, nsrf)*pctsrf(i, nsrf) - ENDDO - ENDDO + ztsol = sum(ftsol * pctsrf, dim = 2) IF (if_ebil >= 1) THEN - ztit = 'after dynamics' - CALL diagetpq(airephy, ztit, ip_ebil, 1, 1, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - ! Comme les tendances de la physique sont ajoutés dans la + tit = 'after dynamics' + CALL diagetpq(airephy, tit, ip_ebil, 1, 1, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) + ! Comme les tendances de la physique sont ajout\'es dans la ! dynamique, la variation d'enthalpie par la dynamique devrait - ! être égale à la variation de la physique au pas de temps - ! précédent. Donc la somme de ces 2 variations devrait être + ! \^etre \'egale \`a la variation de la physique au pas de temps + ! pr\'ec\'edent. Donc la somme de ces 2 variations devrait \^etre ! nulle. - call diagphy(airephy, ztit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & + call diagphy(airephy, tit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & zero_v, zero_v, zero_v, zero_v, ztsol, d_h_vcol + d_h_vcol_phy, & - d_qt, 0., fs_bound, fq_bound) + d_qt, 0.) END IF ! Diagnostic de la tendance dynamique : @@ -878,8 +706,8 @@ ELSE DO k = 1, llm DO i = 1, klon - d_t_dyn(i, k) = 0.0 - d_q_dyn(i, k) = 0.0 + d_t_dyn(i, k) = 0. + d_q_dyn(i, k) = 0. ENDDO ENDDO ancien_ok = .TRUE. @@ -895,23 +723,17 @@ ! Check temperatures: CALL hgardfou(t_seri, ftsol) - ! Incrementer le compteur de la physique + ! Incrémenter le compteur de la physique itap = itap + 1 - julien = MOD(NINT(rdayvrai), 360) + julien = MOD(dayvrai, 360) if (julien == 0) julien = 360 - forall (k = 1: llm) zmasse(:, k) = (paprs(:, k)-paprs(:, k + 1)) / rg + forall (k = 1: llm) zmasse(:, k) = (paprs(:, k) - paprs(:, k + 1)) / rg - ! Mettre en action les conditions aux limites (albedo, sst, etc.). + ! Prescrire l'ozone : + wo = ozonecm(REAL(julien), paprs) - ! Prescrire l'ozone et calculer l'albedo sur l'ocean. - if (nqmx >= 5) then - wo = qx(:, :, 5) * zmasse / dobson_u / 1e3 - else IF (MOD(itap - 1, lmt_pas) == 0) THEN - wo = ozonecm(REAL(julien), paprs) - ENDIF - - ! Évaporation de l'eau liquide nuageuse : + ! \'Evaporation de l'eau liquide nuageuse : DO k = 1, llm DO i = 1, klon zb = MAX(0., ql_seri(i, k)) @@ -923,79 +745,53 @@ ql_seri = 0. IF (if_ebil >= 2) THEN - ztit = 'after reevap' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 1, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - call diagphy(airephy, ztit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & - zero_v, zero_v, zero_v, zero_v, ztsol, d_h_vcol, d_qt, d_ec, & - fs_bound, fq_bound) - + tit = 'after reevap' + CALL diagetpq(airephy, tit, ip_ebil, 2, 1, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) + call diagphy(airephy, tit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & + zero_v, zero_v, zero_v, zero_v, ztsol, d_h_vcol, d_qt, d_ec) END IF - ! Appeler la diffusion verticale (programme de couche limite) - - DO i = 1, klon - zxrugs(i) = 0.0 - ENDDO - DO nsrf = 1, nbsrf - DO i = 1, klon - frugs(i, nsrf) = MAX(frugs(i, nsrf), 0.000015) - ENDDO - ENDDO - DO nsrf = 1, nbsrf - DO i = 1, klon - zxrugs(i) = zxrugs(i) + frugs(i, nsrf)*pctsrf(i, nsrf) - ENDDO - ENDDO + frugs = MAX(frugs, 0.000015) + zxrugs = sum(frugs * pctsrf, dim = 2) - ! calculs necessaires au calcul de l'albedo dans l'interface + ! Calculs nécessaires au calcul de l'albedo dans l'interface avec + ! la surface. - CALL orbite(REAL(julien), zlongi, dist) + CALL orbite(REAL(julien), longi, dist) IF (cycle_diurne) THEN - zdtime = dtphys * REAL(radpas) - CALL zenang(zlongi, time, zdtime, rmu0, fract) + CALL zenang(longi, time, dtphys * radpas, mu0, fract) ELSE - rmu0 = -999.999 + mu0 = -999.999 ENDIF ! Calcul de l'abedo moyen par maille - albsol(:) = 0. - albsollw(:) = 0. - DO nsrf = 1, nbsrf - DO i = 1, klon - albsol(i) = albsol(i) + falbe(i, nsrf) * pctsrf(i, nsrf) - albsollw(i) = albsollw(i) + falblw(i, nsrf) * pctsrf(i, nsrf) - ENDDO - ENDDO + albsol = sum(falbe * pctsrf, dim = 2) - ! Repartition sous maille des flux LW et SW - ! Repartition du longwave par sous-surface linearisee + ! R\'epartition sous maille des flux longwave et shortwave + ! R\'epartition du longwave par sous-surface lin\'earis\'ee - DO nsrf = 1, nbsrf - DO i = 1, klon - fsollw(i, nsrf) = sollw(i) & - + 4.0*RSIGMA*ztsol(i)**3 * (ztsol(i)-ftsol(i, nsrf)) - fsolsw(i, nsrf) = solsw(i)*(1.-falbe(i, nsrf))/(1.-albsol(i)) - ENDDO - ENDDO + forall (nsrf = 1: nbsrf) + fsollw(:, nsrf) = sollw + 4. * RSIGMA * ztsol**3 & + * (ztsol - ftsol(:, nsrf)) + fsolsw(:, nsrf) = solsw * (1. - falbe(:, nsrf)) / (1. - albsol) + END forall fder = dlw ! Couche limite: - CALL clmain(dtphys, itap, date0, pctsrf, pctsrf_new, t_seri, q_seri, & - u_seri, v_seri, julien, rmu0, co2_ppm, ok_veget, ocean, npas, nexca, & - ftsol, soil_model, cdmmax, cdhmax, ksta, ksta_ter, ok_kzmin, ftsoil, & - qsol, paprs, play, fsnow, fqsurf, fevap, falbe, falblw, fluxlat, & - rain_fall, snow_fall, fsolsw, fsollw, sollwdown, fder, rlon, rlat, & - cuphy, cvphy, frugs, firstcal, lafin, agesno, rugoro, d_t_vdf, & - d_q_vdf, d_u_vdf, d_v_vdf, d_ts, fluxt, fluxq, fluxu, fluxv, cdragh, & - cdragm, q2, dsens, devap, ycoefh, yu1, yv1, t2m, q2m, u10m, v10m, & - pblh, capCL, oliqCL, cteiCL, pblT, therm, trmb1, trmb2, trmb3, plcl, & - fqcalving, ffonte, run_off_lic_0, fluxo, fluxg, tslab, seaice) + CALL clmain(dtphys, itap, pctsrf, pctsrf_new, t_seri, q_seri, u_seri, & + v_seri, julien, mu0, co2_ppm, ftsol, cdmmax, cdhmax, ksta, ksta_ter, & + ok_kzmin, ftsoil, qsol, paprs, play, fsnow, fqsurf, fevap, falbe, & + fluxlat, rain_fall, snow_fall, fsolsw, fsollw, fder, rlat, frugs, & + firstcal, agesno, rugoro, d_t_vdf, d_q_vdf, d_u_vdf, d_v_vdf, d_ts, & + fluxt, fluxq, fluxu, fluxv, cdragh, cdragm, q2, dsens, devap, & + ycoefh, yu1, yv1, t2m, q2m, u10m, v10m, pblh, capCL, oliqCL, cteiCL, & + pblT, therm, trmb1, trmb2, trmb3, plcl, fqcalving, ffonte, & + run_off_lic_0, fluxo, fluxg, tslab) - ! Incrémentation des flux + ! Incr\'ementation des flux zxfluxt = 0. zxfluxq = 0. @@ -1004,20 +800,16 @@ DO nsrf = 1, nbsrf DO k = 1, llm DO i = 1, klon - zxfluxt(i, k) = zxfluxt(i, k) + & - fluxt(i, k, nsrf) * pctsrf(i, nsrf) - zxfluxq(i, k) = zxfluxq(i, k) + & - fluxq(i, k, nsrf) * pctsrf(i, nsrf) - zxfluxu(i, k) = zxfluxu(i, k) + & - fluxu(i, k, nsrf) * pctsrf(i, nsrf) - zxfluxv(i, k) = zxfluxv(i, k) + & - fluxv(i, k, nsrf) * pctsrf(i, nsrf) + zxfluxt(i, k) = zxfluxt(i, k) + fluxt(i, k, nsrf) * pctsrf(i, nsrf) + zxfluxq(i, k) = zxfluxq(i, k) + fluxq(i, k, nsrf) * pctsrf(i, nsrf) + zxfluxu(i, k) = zxfluxu(i, k) + fluxu(i, k, nsrf) * pctsrf(i, nsrf) + zxfluxv(i, k) = zxfluxv(i, k) + fluxv(i, k, nsrf) * pctsrf(i, nsrf) END DO END DO END DO DO i = 1, klon sens(i) = - zxfluxt(i, 1) ! flux de chaleur sensible au sol - evap(i) = - zxfluxq(i, 1) ! flux d'evaporation au sol + evap(i) = - zxfluxq(i, 1) ! flux d'\'evaporation au sol fder(i) = dlw(i) + dsens(i) + devap(i) ENDDO @@ -1031,45 +823,41 @@ ENDDO IF (if_ebil >= 2) THEN - ztit = 'after clmain' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - call diagphy(airephy, ztit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & - sens, evap, zero_v, zero_v, ztsol, d_h_vcol, d_qt, d_ec, & - fs_bound, fq_bound) + tit = 'after clmain' + CALL diagetpq(airephy, tit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) + call diagphy(airephy, tit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & + sens, evap, zero_v, zero_v, ztsol, d_h_vcol, d_qt, d_ec) END IF ! Update surface temperature: DO i = 1, klon - zxtsol(i) = 0.0 - zxfluxlat(i) = 0.0 + zxtsol(i) = 0. + zxfluxlat(i) = 0. - zt2m(i) = 0.0 - zq2m(i) = 0.0 - zu10m(i) = 0.0 - zv10m(i) = 0.0 - zxffonte(i) = 0.0 - zxfqcalving(i) = 0.0 - - s_pblh(i) = 0.0 - s_lcl(i) = 0.0 - s_capCL(i) = 0.0 - s_oliqCL(i) = 0.0 - s_cteiCL(i) = 0.0 - s_pblT(i) = 0.0 - s_therm(i) = 0.0 - s_trmb1(i) = 0.0 - s_trmb2(i) = 0.0 - s_trmb3(i) = 0.0 - - IF (abs(pctsrf(i, is_ter) + pctsrf(i, is_lic) + & - pctsrf(i, is_oce) + pctsrf(i, is_sic) - 1.) > EPSFRA) & - THEN - WRITE(*, *) 'physiq : pb sous surface au point ', i, & - pctsrf(i, 1 : nbsrf) - ENDIF + zt2m(i) = 0. + zq2m(i) = 0. + zu10m(i) = 0. + zv10m(i) = 0. + zxffonte(i) = 0. + zxfqcalving(i) = 0. + + s_pblh(i) = 0. + s_lcl(i) = 0. + s_capCL(i) = 0. + s_oliqCL(i) = 0. + s_cteiCL(i) = 0. + s_pblT(i) = 0. + s_therm(i) = 0. + s_trmb1(i) = 0. + s_trmb2(i) = 0. + s_trmb3(i) = 0. + + IF (abs(pctsrf(i, is_ter) + pctsrf(i, is_lic) + pctsrf(i, is_oce) & + + pctsrf(i, is_sic) - 1.) > EPSFRA) print *, & + 'physiq : probl\`eme sous surface au point ', i, & + pctsrf(i, 1 : nbsrf) ENDDO DO nsrf = 1, nbsrf DO i = 1, klon @@ -1097,8 +885,7 @@ ENDDO ENDDO - ! Si une sous-fraction n'existe pas, elle prend la temp. moyenne - + ! Si une sous-fraction n'existe pas, elle prend la température moyenne : DO nsrf = 1, nbsrf DO i = 1, klon IF (pctsrf(i, nsrf) < epsfra) ftsol(i, nsrf) = zxtsol(i) @@ -1123,119 +910,61 @@ ENDDO ENDDO - ! Calculer la derive du flux infrarouge + ! Calculer la dérive du flux infrarouge DO i = 1, klon - dlw(i) = - 4.0*RSIGMA*zxtsol(i)**3 + dlw(i) = - 4. * RSIGMA * zxtsol(i)**3 ENDDO - ! Appeler la convection (au choix) + IF (check) print *, "avantcon = ", qcheck(paprs, q_seri, ql_seri) - DO k = 1, llm - DO i = 1, klon - conv_q(i, k) = d_q_dyn(i, k) & - + d_q_vdf(i, k)/dtphys - conv_t(i, k) = d_t_dyn(i, k) & - + d_t_vdf(i, k)/dtphys - ENDDO - ENDDO - IF (check) THEN - za = qcheck(klon, llm, paprs, q_seri, ql_seri, airephy) - print *, "avantcon = ", za - ENDIF - zx_ajustq = .FALSE. - IF (iflag_con == 2) zx_ajustq = .TRUE. - IF (zx_ajustq) THEN - DO i = 1, klon - z_avant(i) = 0.0 - ENDDO - DO k = 1, llm - DO i = 1, klon - z_avant(i) = z_avant(i) + (q_seri(i, k) + ql_seri(i, k)) & - *zmasse(i, k) - ENDDO - ENDDO - ENDIF + ! Appeler la convection (au choix) - select case (iflag_con) - case (1) - print *, 'Réactiver l''appel à "conlmd" dans "physiq.F".' - stop 1 - case (2) - CALL conflx(dtphys, paprs, play, t_seri, q_seri, conv_t, conv_q, & - zxfluxq(1, 1), omega, d_t_con, d_q_con, rain_con, snow_con, pmfu, & - pmfd, pen_u, pde_u, pen_d, pde_d, kcbot, kctop, kdtop, pmflxr, & - pmflxs) + if (iflag_con == 2) then + conv_q = d_q_dyn + d_q_vdf / dtphys + conv_t = d_t_dyn + d_t_vdf / dtphys + z_avant = sum((q_seri + ql_seri) * zmasse, dim=2) + CALL conflx(dtphys, paprs, play, t_seri(:, llm:1:-1), & + q_seri(:, llm:1:-1), conv_t, conv_q, zxfluxq(:, 1), omega, & + d_t_con, d_q_con, rain_con, snow_con, mfu(:, llm:1:-1), & + mfd(:, llm:1:-1), pen_u, pde_u, pen_d, pde_d, kcbot, kctop, & + kdtop, pmflxr, pmflxs) WHERE (rain_con < 0.) rain_con = 0. WHERE (snow_con < 0.) snow_con = 0. - DO i = 1, klon - ibas_con(i) = llm + 1 - kcbot(i) - itop_con(i) = llm + 1 - kctop(i) - ENDDO - case (3:) - ! number of tracers for the convection scheme of Kerry Emanuel: - ! la partie traceurs est faite dans phytrac - ! on met ntra = 1 pour limiter les appels mais on peut - ! supprimer les calculs / ftra. - ntra = 1 - ! Schéma de convection modularisé et vectorisé : - ! (driver commun aux versions 3 et 4) - - IF (ok_cvl) THEN - ! new driver for convectL - CALL concvl(iflag_con, dtphys, paprs, play, t_seri, q_seri, & - u_seri, v_seri, tr_seri, ntra, ema_work1, ema_work2, d_t_con, & - d_q_con, d_u_con, d_v_con, d_tr, rain_con, snow_con, ibas_con, & - itop_con, upwd, dnwd, dnwd0, Ma, cape, tvp, iflagctrl, pbase, & - bbase, dtvpdt1, dtvpdq1, dplcldt, dplcldr, qcondc, wd, pmflxr, & - pmflxs, da, phi, mp) - clwcon0 = qcondc - pmfu = upwd + dnwd - ELSE - ! conema3 ne contient pas les traceurs - CALL conema3(dtphys, paprs, play, t_seri, q_seri, u_seri, v_seri, & - tr_seri, ntra, ema_work1, ema_work2, d_t_con, d_q_con, & - d_u_con, d_v_con, d_tr, rain_con, snow_con, ibas_con, & - itop_con, upwd, dnwd, dnwd0, bas, top, Ma, cape, tvp, rflag, & - pbase, bbase, dtvpdt1, dtvpdq1, dplcldt, dplcldr, clwcon0) - ENDIF + ibas_con = llm + 1 - kcbot + itop_con = llm + 1 - kctop + else + ! iflag_con >= 3 - IF (.NOT. ok_gust) THEN - do i = 1, klon - wd(i) = 0.0 - enddo + da = 0. + mp = 0. + phi = 0. + CALL concvl(dtphys, paprs, play, t_seri, q_seri, u_seri, v_seri, sig1, & + w01, d_t_con, d_q_con, d_u_con, d_v_con, rain_con, snow_con, & + ibas_con, itop_con, upwd, dnwd, dnwd0, Ma, cape, iflagctrl, & + qcondc, wd, pmflxr, pmflxs, da, phi, mp) + clwcon0 = qcondc + mfu = upwd + dnwd + IF (.NOT. ok_gust) wd = 0. + + IF (thermcep) THEN + zqsat = MIN(0.5, r2es * FOEEW(t_seri, rtt >= t_seri) / play) + zqsat = zqsat / (1. - retv * zqsat) + ELSE + zqsat = merge(qsats(t_seri), qsatl(t_seri), t_seri < t_coup) / play ENDIF - ! Calcul des propriétés des nuages convectifs - - DO k = 1, llm - DO i = 1, klon - zx_t = t_seri(i, k) - IF (thermcep) THEN - zdelta = MAX(0., SIGN(1., rtt-zx_t)) - zx_qs = r2es * FOEEW(zx_t, zdelta)/play(i, k) - zx_qs = MIN(0.5, zx_qs) - zcor = 1./(1.-retv*zx_qs) - zx_qs = zx_qs*zcor - ELSE - IF (zx_t < t_coup) THEN - zx_qs = qsats(zx_t)/play(i, k) - ELSE - zx_qs = qsatl(zx_t)/play(i, k) - ENDIF - ENDIF - zqsat(i, k) = zx_qs - ENDDO - ENDDO - - ! calcul des proprietes des nuages convectifs - clwcon0 = fact_cldcon*clwcon0 - call clouds_gno & - (klon, llm, q_seri, zqsat, clwcon0, ptconv, ratqsc, rnebcon0) - case default - print *, "iflag_con non-prevu", iflag_con - stop 1 - END select + ! Properties of convective clouds + clwcon0 = fact_cldcon * clwcon0 + call clouds_gno(klon, llm, q_seri, zqsat, clwcon0, ptconv, ratqsc, & + rnebcon0) + + mfd = 0. + pen_u = 0. + pen_d = 0. + pde_d = 0. + pde_u = 0. + END if DO k = 1, llm DO i = 1, klon @@ -1247,42 +976,30 @@ ENDDO IF (if_ebil >= 2) THEN - ztit = 'after convect' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - call diagphy(airephy, ztit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & - zero_v, zero_v, rain_con, snow_con, ztsol, d_h_vcol, d_qt, d_ec, & - fs_bound, fq_bound) + tit = 'after convect' + CALL diagetpq(airephy, tit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) + call diagphy(airephy, tit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & + zero_v, zero_v, rain_con, snow_con, ztsol, d_h_vcol, d_qt, d_ec) END IF IF (check) THEN - za = qcheck(klon, llm, paprs, q_seri, ql_seri, airephy) - print *,"aprescon = ", za - zx_t = 0.0 - za = 0.0 + za = qcheck(paprs, q_seri, ql_seri) + print *, "aprescon = ", za + zx_t = 0. + za = 0. DO i = 1, klon za = za + airephy(i)/REAL(klon) zx_t = zx_t + (rain_con(i)+ & snow_con(i))*airephy(i)/REAL(klon) ENDDO zx_t = zx_t/za*dtphys - print *,"Precip = ", zx_t + print *, "Precip = ", zx_t ENDIF - IF (zx_ajustq) THEN - DO i = 1, klon - z_apres(i) = 0.0 - ENDDO - DO k = 1, llm - DO i = 1, klon - z_apres(i) = z_apres(i) + (q_seri(i, k) + ql_seri(i, k)) & - *zmasse(i, k) - ENDDO - ENDDO - DO i = 1, klon - z_factor(i) = (z_avant(i)-(rain_con(i) + snow_con(i))*dtphys) & - /z_apres(i) - ENDDO + + IF (iflag_con == 2) THEN + z_apres = sum((q_seri + ql_seri) * zmasse, dim=2) + z_factor = (z_avant - (rain_con + snow_con) * dtphys) / z_apres DO k = 1, llm DO i = 1, klon IF (z_factor(i) > 1. + 1E-8 .OR. z_factor(i) < 1. - 1E-8) THEN @@ -1291,9 +1008,8 @@ ENDDO ENDDO ENDIF - zx_ajustq = .FALSE. - ! Convection sèche (thermiques ou ajustement) + ! Convection s\`eche (thermiques ou ajustement) d_t_ajs = 0. d_u_ajs = 0. @@ -1314,22 +1030,21 @@ endif IF (if_ebil >= 2) THEN - ztit = 'after dry_adjust' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) + tit = 'after dry_adjust' + CALL diagetpq(airephy, tit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) END IF ! Caclul des ratqs - ! ratqs convectifs a l'ancienne en fonction de q(z = 0)-q / q - ! on ecrase le tableau ratqsc calcule par clouds_gno + ! ratqs convectifs \`a l'ancienne en fonction de (q(z = 0) - q) / q + ! on \'ecrase le tableau ratqsc calcul\'e par clouds_gno if (iflag_cldcon == 1) then do k = 1, llm do i = 1, klon if(ptconv(i, k)) then - ratqsc(i, k) = ratqsbas & - +fact_cldcon*(q_seri(i, 1)-q_seri(i, k))/q_seri(i, k) + ratqsc(i, k) = ratqsbas + fact_cldcon & + * (q_seri(i, 1) - q_seri(i, k)) / q_seri(i, k) else ratqsc(i, k) = 0. endif @@ -1340,27 +1055,24 @@ ! ratqs stables do k = 1, llm do i = 1, klon - ratqss(i, k) = ratqsbas + (ratqshaut-ratqsbas)* & - min((paprs(i, 1)-play(i, k))/(paprs(i, 1)-30000.), 1.) + ratqss(i, k) = ratqsbas + (ratqshaut - ratqsbas) & + * min((paprs(i, 1) - play(i, k)) / (paprs(i, 1) - 3e4), 1.) enddo enddo ! ratqs final - if (iflag_cldcon == 1 .or.iflag_cldcon == 2) then + if (iflag_cldcon == 1 .or. iflag_cldcon == 2) then ! les ratqs sont une conbinaison de ratqss et ratqsc ! ratqs final ! 1e4 (en gros 3 heures), en dur pour le moment, est le temps de ! relaxation des ratqs - facteur = exp(-dtphys*facttemps) - ratqs = max(ratqs*facteur, ratqss) + ratqs = max(ratqs * exp(- dtphys * facttemps), ratqss) ratqs = max(ratqs, ratqsc) else ! on ne prend que le ratqs stable pour fisrtilp ratqs = ratqss endif - ! Processus de condensation à grande echelle et processus de - ! précipitation : CALL fisrtilp(dtphys, paprs, play, t_seri, q_seri, ptconv, ratqs, & d_t_lsc, d_q_lsc, d_ql_lsc, rneb, cldliq, rain_lsc, snow_lsc, & pfrac_impa, pfrac_nucl, pfrac_1nucl, frac_impa, frac_nucl, prfl, & @@ -1378,34 +1090,33 @@ ENDDO ENDDO IF (check) THEN - za = qcheck(klon, llm, paprs, q_seri, ql_seri, airephy) - print *,"apresilp = ", za - zx_t = 0.0 - za = 0.0 + za = qcheck(paprs, q_seri, ql_seri) + print *, "apresilp = ", za + zx_t = 0. + za = 0. DO i = 1, klon za = za + airephy(i)/REAL(klon) zx_t = zx_t + (rain_lsc(i) & + snow_lsc(i))*airephy(i)/REAL(klon) ENDDO zx_t = zx_t/za*dtphys - print *,"Precip = ", zx_t + print *, "Precip = ", zx_t ENDIF IF (if_ebil >= 2) THEN - ztit = 'after fisrt' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - call diagphy(airephy, ztit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & - zero_v, zero_v, rain_lsc, snow_lsc, ztsol, d_h_vcol, d_qt, d_ec, & - fs_bound, fq_bound) + tit = 'after fisrt' + CALL diagetpq(airephy, tit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) + call diagphy(airephy, tit, ip_ebil, zero_v, zero_v, zero_v, zero_v, & + zero_v, zero_v, rain_lsc, snow_lsc, ztsol, d_h_vcol, d_qt, d_ec) END IF ! PRESCRIPTION DES NUAGES POUR LE RAYONNEMENT ! 1. NUAGES CONVECTIFS - IF (iflag_cldcon.le.-1) THEN ! seulement pour Tiedtke + IF (iflag_cldcon <= -1) THEN + ! seulement pour Tiedtke snow_tiedtke = 0. if (iflag_cldcon == -1) then rain_tiedtke = rain_con @@ -1422,9 +1133,8 @@ endif ! Nuages diagnostiques pour Tiedtke - CALL diagcld1(paprs, play, & - rain_tiedtke, snow_tiedtke, ibas_con, itop_con, & - diafra, dialiq) + CALL diagcld1(paprs, play, rain_tiedtke, snow_tiedtke, ibas_con, & + itop_con, diafra, dialiq) DO k = 1, llm DO i = 1, klon IF (diafra(i, k) > cldfra(i, k)) THEN @@ -1434,15 +1144,15 @@ ENDDO ENDDO ELSE IF (iflag_cldcon == 3) THEN - ! On prend pour les nuages convectifs le max du calcul de la - ! convection et du calcul du pas de temps précédent diminué d'un facteur - ! facttemps - facteur = dtphys *facttemps + ! On prend pour les nuages convectifs le maximum du calcul de + ! la convection et du calcul du pas de temps pr\'ec\'edent diminu\'e + ! d'un facteur facttemps. + facteur = dtphys * facttemps do k = 1, llm do i = 1, klon - rnebcon(i, k) = rnebcon(i, k)*facteur - if (rnebcon0(i, k)*clwcon0(i, k) > rnebcon(i, k)*clwcon(i, k)) & - then + rnebcon(i, k) = rnebcon(i, k) * facteur + if (rnebcon0(i, k) * clwcon0(i, k) & + > rnebcon(i, k) * clwcon(i, k)) then rnebcon(i, k) = rnebcon0(i, k) clwcon(i, k) = clwcon0(i, k) endif @@ -1469,26 +1179,21 @@ ENDIF ! Precipitation totale - DO i = 1, klon rain_fall(i) = rain_con(i) + rain_lsc(i) snow_fall(i) = snow_con(i) + snow_lsc(i) ENDDO - IF (if_ebil >= 2) THEN - ztit = "after diagcld" - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - END IF + IF (if_ebil >= 2) CALL diagetpq(airephy, "after diagcld", ip_ebil, 2, 2, & + dtphys, t_seri, q_seri, ql_seri, u_seri, v_seri, paprs, d_h_vcol, & + d_qt, d_ec) - ! Humidité relative pour diagnostic: + ! Humidit\'e relative pour diagnostic : DO k = 1, llm DO i = 1, klon zx_t = t_seri(i, k) IF (thermcep) THEN - zdelta = MAX(0., SIGN(1., rtt-zx_t)) - zx_qs = r2es * FOEEW(zx_t, zdelta)/play(i, k) + zx_qs = r2es * FOEEW(zx_t, rtt >= zx_t)/play(i, k) zx_qs = MIN(0.5, zx_qs) zcor = 1./(1.-retv*zx_qs) zx_qs = zx_qs*zcor @@ -1505,13 +1210,11 @@ ENDDO ! Introduce the aerosol direct and first indirect radiative forcings: - ! Johannes Quaas, 27/11/2003 (quaas@lmd.jussieu.fr) IF (ok_ade .OR. ok_aie) THEN - ! Get sulfate aerosol distribution - CALL readsulfate(rdayvrai, firstcal, sulfate) - CALL readsulfate_preind(rdayvrai, firstcal, sulfate_pi) + ! Get sulfate aerosol distribution : + CALL readsulfate(dayvrai, time, firstcal, sulfate) + CALL readsulfate_preind(dayvrai, time, firstcal, sulfate_pi) - ! Calculate aerosol optical properties (Olivier Boucher) CALL aeropt(play, paprs, t_seri, sulfate, rhcl, tau_ae, piz_ae, cg_ae, & aerindex) ELSE @@ -1520,41 +1223,31 @@ cg_ae = 0. ENDIF - ! Paramètres optiques des nuages et quelques paramètres pour + ! Param\`etres optiques des nuages et quelques param\`etres pour ! diagnostics : if (ok_newmicro) then - CALL newmicro(paprs, play, ok_newmicro, t_seri, cldliq, cldfra, & - cldtau, cldemi, cldh, cldl, cldm, cldt, cldq, flwp, fiwp, flwc, & - fiwc, ok_aie, sulfate, sulfate_pi, bl95_b0, bl95_b1, cldtaupi, & - re, fl) + CALL newmicro(paprs, play, t_seri, cldliq, cldfra, cldtau, cldemi, & + cldh, cldl, cldm, cldt, cldq, flwp, fiwp, flwc, fiwc, ok_aie, & + sulfate, sulfate_pi, bl95_b0, bl95_b1, cldtaupi, re, fl) else CALL nuage(paprs, play, t_seri, cldliq, cldfra, cldtau, cldemi, cldh, & cldl, cldm, cldt, cldq, ok_aie, sulfate, sulfate_pi, bl95_b0, & bl95_b1, cldtaupi, re, fl) endif - ! Appeler le rayonnement mais calculer tout d'abord l'albedo du sol. - IF (MOD(itaprad, radpas) == 0) THEN - DO i = 1, klon - albsol(i) = falbe(i, is_oce) * pctsrf(i, is_oce) & - + falbe(i, is_lic) * pctsrf(i, is_lic) & - + falbe(i, is_ter) * pctsrf(i, is_ter) & - + falbe(i, is_sic) * pctsrf(i, is_sic) - albsollw(i) = falblw(i, is_oce) * pctsrf(i, is_oce) & - + falblw(i, is_lic) * pctsrf(i, is_lic) & - + falblw(i, is_ter) * pctsrf(i, is_ter) & - + falblw(i, is_sic) * pctsrf(i, is_sic) - ENDDO - ! nouveau rayonnement (compatible Arpege-IFS): - CALL radlwsw(dist, rmu0, fract, paprs, play, zxtsol, albsol, & - albsollw, t_seri, q_seri, wo, cldfra, cldemi, cldtau, heat, & - heat0, cool, cool0, radsol, albpla, topsw, toplw, solsw, sollw, & - sollwdown, topsw0, toplw0, solsw0, sollw0, lwdn0, lwdn, lwup0, & - lwup, swdn0, swdn, swup0, swup, ok_ade, ok_aie, tau_ae, piz_ae, & - cg_ae, topswad, solswad, cldtaupi, topswai, solswai) - itaprad = 0 + IF (MOD(itap - 1, radpas) == 0) THEN + ! Appeler le rayonnement mais calculer tout d'abord l'albedo du sol. + ! Calcul de l'abedo moyen par maille + albsol = sum(falbe * pctsrf, dim = 2) + + ! Rayonnement (compatible Arpege-IFS) : + CALL radlwsw(dist, mu0, fract, paprs, play, zxtsol, albsol, t_seri, & + q_seri, wo, cldfra, cldemi, cldtau, heat, heat0, cool, cool0, & + radsol, albpla, topsw, toplw, solsw, sollw, sollwdown, topsw0, & + toplw0, solsw0, sollw0, lwdn0, lwdn, lwup0, lwup, swdn0, swdn, & + swup0, swup, ok_ade, ok_aie, tau_ae, piz_ae, cg_ae, topswad, & + solswad, cldtaupi, topswai, solswai) ENDIF - itaprad = itaprad + 1 ! Ajouter la tendance des rayonnements (tous les pas) @@ -1565,19 +1258,17 @@ ENDDO IF (if_ebil >= 2) THEN - ztit = 'after rad' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - call diagphy(airephy, ztit, ip_ebil, topsw, toplw, solsw, sollw, & - zero_v, zero_v, zero_v, zero_v, ztsol, d_h_vcol, d_qt, d_ec, & - fs_bound, fq_bound) + tit = 'after rad' + CALL diagetpq(airephy, tit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) + call diagphy(airephy, tit, ip_ebil, topsw, toplw, solsw, sollw, & + zero_v, zero_v, zero_v, zero_v, ztsol, d_h_vcol, d_qt, d_ec) END IF ! Calculer l'hydrologie de la surface DO i = 1, klon - zxqsurf(i) = 0.0 - zxsnow(i) = 0.0 + zxqsurf(i) = 0. + zxsnow(i) = 0. ENDDO DO nsrf = 1, nbsrf DO i = 1, klon @@ -1586,20 +1277,20 @@ ENDDO ENDDO - ! Calculer le bilan du sol et la dérive de température (couplage) + ! Calculer le bilan du sol et la d\'erive de temp\'erature (couplage) DO i = 1, klon bils(i) = radsol(i) - sens(i) + zxfluxlat(i) ENDDO - ! Paramétrisation de l'orographie à l'échelle sous-maille : + ! Param\'etrisation de l'orographie \`a l'\'echelle sous-maille : IF (ok_orodr) THEN ! selection des points pour lesquels le shema est actif: igwd = 0 DO i = 1, klon itest(i) = 0 - IF (((zpic(i)-zmea(i)) > 100.).AND.(zstd(i) > 10.0)) THEN + IF (((zpic(i)-zmea(i)) > 100.).AND.(zstd(i) > 10.)) THEN itest(i) = 1 igwd = igwd + 1 idx(igwd) = i @@ -1607,8 +1298,8 @@ ENDDO CALL drag_noro(klon, llm, dtphys, paprs, play, zmea, zstd, zsig, zgam, & - zthe, zpic, zval, igwd, idx, itest, t_seri, u_seri, v_seri, & - zulow, zvlow, zustrdr, zvstrdr, d_t_oro, d_u_oro, d_v_oro) + zthe, zpic, zval, itest, t_seri, u_seri, v_seri, zulow, zvlow, & + zustrdr, zvstrdr, d_t_oro, d_u_oro, d_v_oro) ! ajout des tendances DO k = 1, llm @@ -1621,7 +1312,7 @@ ENDIF IF (ok_orolf) THEN - ! Sélection des points pour lesquels le schéma est actif : + ! S\'election des points pour lesquels le sch\'ema est actif : igwd = 0 DO i = 1, klon itest(i) = 0 @@ -1646,7 +1337,7 @@ ENDDO ENDIF - ! STRESS NECESSAIRES: TOUTE LA PHYSIQUE + ! Stress n\'ecessaires : toute la physique DO i = 1, klon zustrph(i) = 0. @@ -1654,34 +1345,29 @@ ENDDO DO k = 1, llm DO i = 1, klon - zustrph(i) = zustrph(i) + (u_seri(i, k)-u(i, k))/dtphys* zmasse(i, k) - zvstrph(i) = zvstrph(i) + (v_seri(i, k)-v(i, k))/dtphys* zmasse(i, k) + zustrph(i) = zustrph(i) + (u_seri(i, k) - u(i, k)) / dtphys & + * zmasse(i, k) + zvstrph(i) = zvstrph(i) + (v_seri(i, k) - v(i, k)) / dtphys & + * zmasse(i, k) ENDDO ENDDO CALL aaam_bud(ra, rg, romega, rlat, rlon, pphis, zustrdr, zustrli, & zustrph, zvstrdr, zvstrli, zvstrph, paprs, u, v, aam, torsfc) - IF (if_ebil >= 2) THEN - ztit = 'after orography' - CALL diagetpq(airephy, ztit, ip_ebil, 2, 2, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) - END IF + IF (if_ebil >= 2) CALL diagetpq(airephy, 'after orography', ip_ebil, 2, & + 2, dtphys, t_seri, q_seri, ql_seri, u_seri, v_seri, paprs, d_h_vcol, & + d_qt, d_ec) ! Calcul des tendances traceurs - call phytrac(rnpb, itap, lmt_pas, julien, time, firstcal, lafin, & - nqmx-2, dtphys, u, t, paprs, play, pmfu, pmfd, pen_u, pde_u, & - pen_d, pde_d, ycoefh, fm_therm, entr_therm, yu1, yv1, ftsol, pctsrf, & - frac_impa, frac_nucl, pphis, albsol, rhcl, cldfra, rneb, & - diafra, cldliq, pmflxr, pmflxs, prfl, psfl, da, phi, mp, upwd, dnwd, & - tr_seri, zmasse) - - IF (offline) THEN - call phystokenc(dtphys, rlon, rlat, t, pmfu, pmfd, pen_u, pde_u, & - pen_d, pde_d, fm_therm, entr_therm, ycoefh, yu1, yv1, ftsol, & - pctsrf, frac_impa, frac_nucl, pphis, airephy, dtphys, itap) - ENDIF + call phytrac(itap, lmt_pas, julien, time, firstcal, lafin, dtphys, t, & + paprs, play, mfu, mfd, pde_u, pen_d, ycoefh, fm_therm, entr_therm, & + yu1, yv1, ftsol, pctsrf, frac_impa, frac_nucl, pphis, da, phi, mp, & + upwd, dnwd, tr_seri, zmasse) + + IF (offline) call phystokenc(dtphys, rlon, rlat, t, mfu, mfd, pen_u, & + pde_u, pen_d, pde_d, fm_therm, entr_therm, ycoefh, yu1, yv1, ftsol, & + pctsrf, frac_impa, frac_nucl, pphis, airephy, dtphys, itap) ! Calculer le transport de l'eau et de l'energie (diagnostique) CALL transp(paprs, zxtsol, t_seri, q_seri, u_seri, v_seri, zphi, ve, vq, & @@ -1706,25 +1392,21 @@ END DO IF (if_ebil >= 1) THEN - ztit = 'after physic' - CALL diagetpq(airephy, ztit, ip_ebil, 1, 1, dtphys, t_seri, q_seri, & - ql_seri, qs_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_qw, & - d_ql, d_qs, d_ec) + tit = 'after physic' + CALL diagetpq(airephy, tit, ip_ebil, 1, 1, dtphys, t_seri, q_seri, & + ql_seri, u_seri, v_seri, paprs, d_h_vcol, d_qt, d_ec) ! Comme les tendances de la physique sont ajoute dans la dynamique, ! on devrait avoir que la variation d'entalpie par la dynamique ! est egale a la variation de la physique au pas de temps precedent. ! Donc la somme de ces 2 variations devrait etre nulle. - call diagphy(airephy, ztit, ip_ebil, topsw, toplw, solsw, sollw, sens, & - evap, rain_fall, snow_fall, ztsol, d_h_vcol, d_qt, d_ec, & - fs_bound, fq_bound) - + call diagphy(airephy, tit, ip_ebil, topsw, toplw, solsw, sollw, sens, & + evap, rain_fall, snow_fall, ztsol, d_h_vcol, d_qt, d_ec) d_h_vcol_phy = d_h_vcol - END IF ! SORTIES - !cc prw = eau precipitable + ! prw = eau precipitable DO i = 1, klon prw(i) = 0. DO k = 1, llm @@ -1744,15 +1426,13 @@ ENDDO ENDDO - IF (nqmx >= 3) THEN - DO iq = 3, nqmx - DO k = 1, llm - DO i = 1, klon - d_qx(i, k, iq) = (tr_seri(i, k, iq-2) - qx(i, k, iq)) / dtphys - ENDDO + DO iq = 3, nqmx + DO k = 1, llm + DO i = 1, klon + d_qx(i, k, iq) = (tr_seri(i, k, iq-2) - qx(i, k, iq)) / dtphys ENDDO ENDDO - ENDIF + ENDDO ! Sauvegarder les valeurs de t et q a la fin de la physique: DO k = 1, llm @@ -1763,84 +1443,43 @@ ENDDO ! Ecriture des sorties - call write_histhf - call write_histday call write_histins ! Si c'est la fin, il faut conserver l'etat de redemarrage IF (lafin) THEN itau_phy = itau_phy + itap - CALL phyredem("restartphy.nc", rlat, rlon, pctsrf, ftsol, ftsoil, & - tslab, seaice, fqsurf, qsol, fsnow, falbe, falblw, fevap, & - rain_fall, snow_fall, solsw, sollwdown, dlw, radsol, frugs, & - agesno, zmea, zstd, zsig, zgam, zthe, zpic, zval, t_ancien, & - q_ancien, rnebcon, ratqs, clwcon, run_off_lic_0) + CALL phyredem("restartphy.nc", pctsrf, ftsol, ftsoil, tslab, seaice, & + fqsurf, qsol, fsnow, falbe, fevap, rain_fall, snow_fall, & + solsw, sollw, dlw, radsol, frugs, agesno, zmea, zstd, zsig, zgam, & + zthe, zpic, zval, t_ancien, q_ancien, rnebcon, ratqs, clwcon, & + run_off_lic_0, sig1, w01) ENDIF firstcal = .FALSE. contains - subroutine write_histday - - use gr_phy_write_3d_m, only: gr_phy_write_3d - integer itau_w ! pas de temps ecriture - - !------------------------------------------------ - - if (ok_journe) THEN - itau_w = itau_phy + itap - if (nqmx <= 4) then - call histwrite(nid_day, "Sigma_O3_Royer", itau_w, & - gr_phy_write_3d(wo) * 1e3) - ! (convert "wo" from kDU to DU) - end if - if (ok_sync) then - call histsync(nid_day) - endif - ENDIF - - End subroutine write_histday - - !**************************** - - subroutine write_histhf - - ! From phylmd/write_histhf.h, version 1.5 2005/05/25 13:10:09 - - !------------------------------------------------ - - call write_histhf3d - - IF (ok_sync) THEN - call histsync(nid_hf) - ENDIF - - end subroutine write_histhf - - !*************************************************************** - subroutine write_histins ! From phylmd/write_histins.h, version 1.2 2005/05/25 13:10:09 - real zout - integer itau_w ! pas de temps ecriture + use dimens_m, only: iim, jjm + USE histsync_m, ONLY: histsync + USE histwrite_m, ONLY: histwrite + + integer i, itau_w ! pas de temps ecriture + REAL zx_tmp_2d(iim, jjm + 1), zx_tmp_3d(iim, jjm + 1, llm) !-------------------------------------------------- IF (ok_instan) THEN ! Champs 2D: - zsto = dtphys * ecrit_ins - zout = dtphys * ecrit_ins itau_w = itau_phy + itap - i = NINT(zout/zsto) CALL gr_fi_ecrit(1, klon, iim, jjm + 1, pphis, zx_tmp_2d) CALL histwrite(nid_ins, "phis", itau_w, zx_tmp_2d) - i = NINT(zout/zsto) CALL gr_fi_ecrit(1, klon, iim, jjm + 1, airephy, zx_tmp_2d) CALL histwrite(nid_ins, "aire", itau_w, zx_tmp_2d) @@ -1972,7 +1611,7 @@ CALL histwrite(nid_ins, "rugs_"//clnsurf(nsrf), itau_w, & zx_tmp_2d) - zx_tmp_fi2d(1 : klon) = falbe(1 : klon, nsrf) + zx_tmp_fi2d(1 : klon) = falbe(:, nsrf) CALL gr_fi_ecrit(1, klon, iim, jjm + 1, zx_tmp_fi2d, zx_tmp_2d) CALL histwrite(nid_ins, "albe_"//clnsurf(nsrf), itau_w, & zx_tmp_2d) @@ -1980,8 +1619,6 @@ END DO CALL gr_fi_ecrit(1, klon, iim, jjm + 1, albsol, zx_tmp_2d) CALL histwrite(nid_ins, "albs", itau_w, zx_tmp_2d) - CALL gr_fi_ecrit(1, klon, iim, jjm + 1, albsollw, zx_tmp_2d) - CALL histwrite(nid_ins, "albslw", itau_w, zx_tmp_2d) CALL gr_fi_ecrit(1, klon, iim, jjm + 1, zxrugs, zx_tmp_2d) CALL histwrite(nid_ins, "rugs", itau_w, zx_tmp_2d) @@ -2041,51 +1678,11 @@ CALL gr_fi_ecrit(llm, klon, iim, jjm + 1, d_q_vdf, zx_tmp_3d) CALL histwrite(nid_ins, "dqvdf", itau_w, zx_tmp_3d) - if (ok_sync) then - call histsync(nid_ins) - endif + call histsync(nid_ins) ENDIF end subroutine write_histins - !**************************************************** - - subroutine write_histhf3d - - ! From phylmd/write_histhf3d.h, version 1.2 2005/05/25 13:10:09 - - integer itau_w ! pas de temps ecriture - - !------------------------------------------------------- - - itau_w = itau_phy + itap - - ! Champs 3D: - - CALL gr_fi_ecrit(llm, klon, iim, jjm + 1, t_seri, zx_tmp_3d) - CALL histwrite(nid_hf3d, "temp", itau_w, zx_tmp_3d) - - CALL gr_fi_ecrit(llm, klon, iim, jjm + 1, qx(1, 1, ivap), zx_tmp_3d) - CALL histwrite(nid_hf3d, "ovap", itau_w, zx_tmp_3d) - - CALL gr_fi_ecrit(llm, klon, iim, jjm + 1, u_seri, zx_tmp_3d) - CALL histwrite(nid_hf3d, "vitu", itau_w, zx_tmp_3d) - - CALL gr_fi_ecrit(llm, klon, iim, jjm + 1, v_seri, zx_tmp_3d) - CALL histwrite(nid_hf3d, "vitv", itau_w, zx_tmp_3d) - - if (nbtr >= 3) then - CALL gr_fi_ecrit(llm, klon, iim, jjm + 1, tr_seri(1, 1, 3), & - zx_tmp_3d) - CALL histwrite(nid_hf3d, "O3", itau_w, zx_tmp_3d) - end if - - if (ok_sync) then - call histsync(nid_hf3d) - endif - - end subroutine write_histhf3d - END SUBROUTINE physiq end module physiq_m