! ! $Id: conema3.F 1403 2010-07-01 09:02:53Z aborella $ ! SUBROUTINE conema3 (dtime,paprs,pplay,t,q,u,v,tra,ntra, . work1,work2,d_t,d_q,d_u,d_v,d_tra, . rain, snow, kbas, ktop, . upwd,dnwd,dnwdbis,bas,top,Ma,cape,tvp,rflag, . pbase,bbase,dtvpdt1,dtvpdq1,dplcldt,dplcldr, . qcond_incld) USE dimphy USE infotrac, ONLY : nbtr IMPLICIT none c====================================================================== c Auteur(s): Z.X. Li (LMD/CNRS) date: 19930818 c Objet: schema de convection de Emanuel (1991) interface c Mai 1998: Interface modifiee pour implementation dans LMDZ c====================================================================== c Arguments: c dtime---input-R-pas d'integration (s) c paprs---input-R-pression inter-couches (Pa) c pplay---input-R-pression au milieu des couches (Pa) c t-------input-R-temperature (K) c q-------input-R-humidite specifique (kg/kg) c u-------input-R-vitesse du vent zonal (m/s) c v-------input-R-vitesse duvent meridien (m/s) c tra-----input-R-tableau de rapport de melange des traceurs c work*: input et output: deux variables de travail, c on peut les mettre a 0 au debut c C d_t-----output-R-increment de la temperature c d_q-----output-R-increment de la vapeur d'eau c d_u-----output-R-increment de la vitesse zonale c d_v-----output-R-increment de la vitesse meridienne c d_tra---output-R-increment du contenu en traceurs c rain----output-R-la pluie (mm/s) c snow----output-R-la neige (mm/s) c kbas----output-R-bas du nuage (integer) c ktop----output-R-haut du nuage (integer) c upwd----output-R-saturated updraft mass flux (kg/m**2/s) c dnwd----output-R-saturated downdraft mass flux (kg/m**2/s) c dnwdbis-output-R-unsaturated downdraft mass flux (kg/m**2/s) c bas-----output-R-bas du nuage (real) c top-----output-R-haut du nuage (real) c Ma------output-R-flux ascendant non dilue (kg/m**2/s) c cape----output-R-CAPE c tvp-----output-R-virtual temperature of the lifted parcel c rflag---output-R-flag sur le fonctionnement de convect c pbase---output-R-pression a la base du nuage (Pa) c bbase---output-R-buoyancy a la base du nuage (K) c dtvpdt1-output-R-derivative of parcel virtual temp wrt T1 c dtvpdq1-output-R-derivative of parcel virtual temp wrt Q1 c dplcldt-output-R-derivative of the PCP pressure wrt T1 c dplcldr-output-R-derivative of the PCP pressure wrt Q1 c====================================================================== c #include "dimensions.h" #include "conema3.h" INTEGER i, l,m,itra INTEGER ntra ! if no tracer transport ! is needed, set ntra = 1 (or 0) REAL dtime c REAL d_t2(klon,klev), d_q2(klon,klev) ! sbl REAL d_u2(klon,klev), d_v2(klon,klev) ! sbl REAL em_d_t2(klev), em_d_q2(klev) ! sbl REAL em_d_u2(klev), em_d_v2(klev) ! sbl c REAL paprs(klon,klev+1), pplay(klon,klev) REAL t(klon,klev), q(klon,klev), d_t(klon,klev), d_q(klon,klev) REAL u(klon,klev), v(klon,klev), tra(klon,klev,ntra) REAL d_u(klon,klev), d_v(klon,klev), d_tra(klon,klev,ntra) REAL work1(klon,klev), work2(klon,klev) REAL upwd(klon,klev), dnwd(klon,klev), dnwdbis(klon,klev) REAL rain(klon) REAL snow(klon) REAL cape(klon), tvp(klon,klev), rflag(klon) REAL pbase(klon), bbase(klon) REAL dtvpdt1(klon,klev), dtvpdq1(klon,klev) REAL dplcldt(klon), dplcldr(klon) INTEGER kbas(klon), ktop(klon) REAL wd(klon) REAL qcond_incld(klon,klev) c LOGICAL,SAVE :: first=.true. c$OMP THREADPRIVATE(first) cym REAL em_t(klev) REAL,ALLOCATABLE,SAVE :: em_t(:) c$OMP THREADPRIVATE(em_t) cym REAL em_q(klev) REAL,ALLOCATABLE,SAVE :: em_q(:) c$OMP THREADPRIVATE(em_q) cym REAL em_qs(klev) REAL,ALLOCATABLE,SAVE :: em_qs(:) c$OMP THREADPRIVATE(em_qs) cym REAL em_u(klev), em_v(klev), em_tra(klev,nbtr) REAL,ALLOCATABLE,SAVE :: em_u(:),em_v(:),em_tra(:,:) c$OMP THREADPRIVATE(em_u,em_v,em_tra) cym REAL em_ph(klev+1), em_p(klev) REAL,ALLOCATABLE,SAVE ::em_ph(:),em_p(:) c$OMP THREADPRIVATE(em_ph,em_p) cym REAL em_work1(klev), em_work2(klev) REAL,ALLOCATABLE,SAVE ::em_work1(:),em_work2(:) c$OMP THREADPRIVATE(em_work1,em_work2) cym REAL em_precip, em_d_t(klev), em_d_q(klev) REAL,SAVE :: em_precip c$OMP THREADPRIVATE(em_precip) REAL,ALLOCATABLE,SAVE :: em_d_t(:),em_d_q(:) c$OMP THREADPRIVATE(em_d_t,em_d_q) cym REAL em_d_u(klev), em_d_v(klev), em_d_tra(klev,nbtr) REAL,ALLOCATABLE,SAVE ::em_d_u(:),em_d_v(:),em_d_tra(:,:) c$OMP THREADPRIVATE(em_d_u,em_d_v,em_d_tra) cym REAL em_upwd(klev), em_dnwd(klev), em_dnwdbis(klev) REAL,ALLOCATABLE,SAVE :: em_upwd(:),em_dnwd(:),em_dnwdbis(:) c$OMP THREADPRIVATE(em_upwd,em_dnwd,em_dnwdbis) REAL em_dtvpdt1(klev), em_dtvpdq1(klev) REAL em_dplcldt, em_dplcldr cym SAVE em_t,em_q, em_qs, em_ph, em_p, em_work1, em_work2 cym SAVE em_u,em_v, em_tra cym SAVE em_d_u,em_d_v, em_d_tra cym SAVE em_precip, em_d_t, em_d_q, em_upwd, em_dnwd, em_dnwdbis INTEGER em_bas, em_top SAVE em_bas, em_top c$OMP THREADPRIVATE(em_bas,em_top) REAL em_wd REAL em_qcond(klev) REAL em_qcondc(klev) c REAL zx_t, zx_qs, zdelta, zcor INTEGER iflag REAL sigsum ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc c VARIABLES A SORTIR cccccccccccccccccccccccccccccccccccccccccccccccccc cym REAL emmip(klev) !variation de flux ascnon dilue i et i+1 REAL,ALLOCATABLE,SAVE ::emmip(:) c$OMP THREADPRIVATE(emmip) cym SAVE emmip cym real emMke(klev) REAL,ALLOCATABLE,SAVE ::emMke(:) c$OMP THREADPRIVATE(emMke) cym save emMke real top real bas cym real emMa(klev) REAL,ALLOCATABLE,SAVE ::emMa(:) c$OMP THREADPRIVATE(emMa) cym save emMa real Ma(klon,klev) real Ment(klev,klev) real Qent(klev,klev) real TPS(klev),TLS(klev) real SIJ(klev,klev) real em_CAPE, em_TVP(klev) real em_pbase, em_bbase integer iw,j,k,ix,iy c -- sb: pour schema nuages: integer iflagcon integer em_ifc(klev) real em_pradj real em_cldf(klev), em_cldq(klev) real em_ftadj(klev), em_fradj(klev) integer ifc(klon,klev) real pradj(klon) real cldf(klon,klev), cldq(klon,klev) real ftadj(klon,klev), fqadj(klon,klev) c sb -- ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc c #include "YOMCST.h" #include "YOETHF.h" #include "FCTTRE.h" if (first) then allocate(em_t(klev)) allocate(em_q(klev)) allocate(em_qs(klev)) allocate(em_u(klev), em_v(klev), em_tra(klev,nbtr)) allocate(em_ph(klev+1), em_p(klev)) allocate(em_work1(klev), em_work2(klev)) allocate(em_d_t(klev), em_d_q(klev)) allocate(em_d_u(klev), em_d_v(klev), em_d_tra(klev,nbtr)) allocate(em_upwd(klev), em_dnwd(klev), em_dnwdbis(klev)) allocate(emmip(klev)) allocate(emMke(klev)) allocate(emMa(klev)) first=.false. endif qcond_incld(:,:) = 0. c c@$$ print*,'debut conema' DO 999 i = 1, klon DO l = 1, klev+1 em_ph(l) = paprs(i,l) / 100.0 ENDDO c DO l = 1, klev em_p(l) = pplay(i,l) / 100.0 em_t(l) = t(i,l) em_q(l) = q(i,l) em_u(l) = u(i,l) em_v(l) = v(i,l) do itra = 1, ntra em_tra(l,itra) = tra(i,l,itra) enddo c@$$ print*,'em_t',em_t c@$$ print*,'em_q',em_q c@$$ print*,'em_qs',em_qs c@$$ print*,'em_u',em_u c@$$ print*,'em_v',em_v c@$$ print*,'em_tra',em_tra c@$$ print*,'em_p',em_p c zx_t = em_t(l) zdelta=MAX(0.,SIGN(1.,rtt-zx_t)) zx_qs= r2es * FOEEW(zx_t,zdelta)/em_p(l)/100.0 zx_qs=MIN(0.5,zx_qs) c@$$ print*,'zx_qs',zx_qs zcor=1./(1.-retv*zx_qs) zx_qs=zx_qs*zcor em_qs(l) = zx_qs c@$$ print*,'em_qs',em_qs c em_work1(l) = work1(i,l) em_work2(l) = work2(i,l) emMke(l)=0 c emMa(l)=0 c Ma(i,l)=0 em_dtvpdt1(l) = 0. em_dtvpdq1(l) = 0. dtvpdt1(i,l) = 0. dtvpdq1(i,l) = 0. ENDDO c em_dplcldt = 0. em_dplcldr = 0. rain(i) = 0.0 snow(i) = 0.0 kbas(i) = 1 ktop(i) = 1 c ajout SB: bas = 1 top = 1 c sb3d write(*,1792) (em_work1(m),m=1,klev) 1792 format('sig avant convect ',/,10(1X,E13.5)) c c sb d write(*,1793) (em_work2(m),m=1,klev) 1793 format('w avant convect ',/,10(1X,E13.5)) c@$$ print*,'avant convect' ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc c c print*,'avant convect i=',i CALL convect3(dtime,epmax,ok_adj_ema, . em_t, em_q, em_qs,em_u ,em_v , . em_tra, em_p, em_ph, . klev, klev+1, klev-1,ntra, dtime, iflag, . em_d_t, em_d_q,em_d_u,em_d_v, . em_d_tra, em_precip, . em_bas, em_top,em_upwd, em_dnwd, em_dnwdbis, . em_work1, em_work2,emmip,emMke,emMa,Ment, . Qent,TPS,TLS,SIJ,em_CAPE,em_TVP,em_pbase,em_bbase, . em_dtvpdt1,em_dtvpdq1,em_dplcldt,em_dplcldr, ! sbl . em_d_t2,em_d_q2,em_d_u2,em_d_v2,em_wd,em_qcond,em_qcondc)!sbl c print*,'apres convect ' c ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc c c -- sb: Appel schema statistique de nuages couple a la convection c (Bony et Emanuel 2001): c -- creer cvthermo.h qui contiendra les cstes thermo de LMDZ: iflagcon = 3 c CALL cv_thermo(iflagcon) c -- appel schema de nuages: c CALL CLOUDS_SUB_LS(klev,em_q,em_qs,em_t c i ,em_p,em_ph,dtime,em_qcondc c o ,em_cldf,em_cldq,em_pradj,em_ftadj,em_fradj,em_ifc) do k = 1, klev cldf(i,k) = em_cldf(k) ! cloud fraction (0-1) cldq(i,k) = em_cldq(k) ! in-cloud water content (kg/kg) ftadj(i,k) = em_ftadj(k) ! (dT/dt)_{LS adj} (K/s) fqadj(i,k) = em_fradj(k) ! (dq/dt)_{LS adj} (kg/kg/s) ifc(i,k) = em_ifc(k) ! flag convergence clouds_gno (1 ou 2) enddo pradj(i) = em_pradj ! precip from LS supersat adj (mm/day) c sb -- c c SB: if (iflag.ne.1 .and. iflag.ne.4) then em_CAPE = 0. do l = 1, klev em_upwd(l) = 0. em_dnwd(l) = 0. em_dnwdbis(l) = 0. emMa(l) = 0. em_TVP(l) = 0. enddo endif c fin SB c c If sig has been set to zero, then set Ma to zero c sigsum = 0. do k = 1,klev sigsum = sigsum + em_work1(k) enddo if (sigsum .eq. 0.0) then do k = 1,klev emMa(k) = 0. enddo endif c c sb3d print*,'i, iflag=',i,iflag c ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc c c SORTIE DES ICB ET INB c en fait inb et icb correspondent au niveau ou se trouve c le nuage,le numero d'interface cccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc c modif SB: if (iflag.EQ.1 .or. iflag.EQ.4) then top=em_top bas=em_bas kbas(i) = em_bas ktop(i) = em_top endif pbase(i) = em_pbase bbase(i) = em_bbase rain(i) = em_precip/ 86400.0 snow(i) = 0.0 cape(i) = em_CAPE wd(i) = em_wd rflag(i) = REAL(iflag) c SB kbas(i) = em_bas c SB ktop(i) = em_top dplcldt(i) = em_dplcldt dplcldr(i) = em_dplcldr DO l = 1, klev d_t2(i,l) = dtime * em_d_t2(l) d_q2(i,l) = dtime * em_d_q2(l) d_u2(i,l) = dtime * em_d_u2(l) d_v2(i,l) = dtime * em_d_v2(l) d_t(i,l) = dtime * em_d_t(l) d_q(i,l) = dtime * em_d_q(l) d_u(i,l) = dtime * em_d_u(l) d_v(i,l) = dtime * em_d_v(l) do itra = 1, ntra d_tra(i,l,itra) = dtime * em_d_tra(l,itra) enddo upwd(i,l) = em_upwd(l) dnwd(i,l) = em_dnwd(l) dnwdbis(i,l) = em_dnwdbis(l) work1(i,l) = em_work1(l) work2(i,l) = em_work2(l) Ma(i,l)=emMa(l) tvp(i,l)=em_TVP(l) dtvpdt1(i,l) = em_dtvpdt1(l) dtvpdq1(i,l) = em_dtvpdq1(l) if (iflag_clw.eq.0) then qcond_incld(i,l) = em_qcondc(l) else if (iflag_clw.eq.1) then qcond_incld(i,l) = em_qcond(l) endif ENDDO 999 CONTINUE c On calcule une eau liquide diagnostique en fonction de la c precip. if ( iflag_clw.eq.2 ) then do l=1,klev do i=1,klon if (ktop(i)-kbas(i).gt.0.and. s l.ge.kbas(i).and.l.le.ktop(i)) then qcond_incld(i,l)=rain(i)*8.e4 c s *(pplay(i,l )-paprs(i,ktop(i)+1)) s /(pplay(i,kbas(i))-pplay(i,ktop(i))) c s **2 else qcond_incld(i,l)=0. endif enddo print*,'l=',l,', qcond_incld=',qcond_incld(1,l) enddo endif RETURN END