subroutine vdifc(ngrid,nlay,nq,rnat,ppopsk, & ptimestep,pcapcal,lecrit, & pplay,pplev,pzlay,pzlev,pz0, & pu,pv,ph,pq,ptsrf,pemis,pqsurf, & pdufi,pdvfi,pdhfi,pdqfi,pfluxsrf, & pdudif,pdvdif,pdhdif,pdtsrf,sensibFlux,pq2, & pdqdif,pdqsdif,lastcall) use watercommon_h, only : RLVTT, T_h2O_ice_liq, RCPD, mx_eau_sol use radcommon_h, only : sigma USE surfdat_h USE comgeomfi_h USE tracer_h implicit none !================================================================== ! ! Purpose ! ------- ! Turbulent diffusion (mixing) for pot. T, U, V and tracers ! ! Implicit scheme ! We start by adding to variables x the physical tendencies ! already computed. We resolve the equation: ! ! x(t+1) = x(t) + dt * (dx/dt)phys(t) + dt * (dx/dt)difv(t+1) ! ! Authors ! ------- ! F. Hourdin, F. Forget, R. Fournier (199X) ! R. Wordsworth, B. Charnay (2010) ! !================================================================== !----------------------------------------------------------------------- ! declarations ! ------------ !#include "dimensions.h" !#include "dimphys.h" #include "comcstfi.h" #include "callkeys.h" ! arguments ! --------- INTEGER ngrid,nlay REAL ptimestep REAL pplay(ngrid,nlay),pplev(ngrid,nlay+1) REAL pzlay(ngrid,nlay),pzlev(ngrid,nlay+1) REAL pu(ngrid,nlay),pv(ngrid,nlay),ph(ngrid,nlay) REAL ptsrf(ngrid),pemis(ngrid) REAL pdufi(ngrid,nlay),pdvfi(ngrid,nlay),pdhfi(ngrid,nlay) REAL pfluxsrf(ngrid) REAL pdudif(ngrid,nlay),pdvdif(ngrid,nlay),pdhdif(ngrid,nlay) REAL pdtsrf(ngrid),sensibFlux(ngrid),pcapcal(ngrid) REAL pq2(ngrid,nlay+1) real rnat(ngrid) ! Arguments added for condensation REAL ppopsk(ngrid,nlay) logical lecrit REAL pz0 ! Tracers ! -------- integer nq real pqsurf(ngrid,nq) real pq(ngrid,nlay,nq), pdqfi(ngrid,nlay,nq) real pdqdif(ngrid,nlay,nq) real pdqsdif(ngrid,nq) ! local ! ----- integer ilev,ig,ilay,nlev REAL z4st,zdplanck(ngrid) REAL zkv(ngrid,nlay+1),zkh(ngrid,nlay+1) REAL zcdv(ngrid),zcdh(ngrid) REAL zcdv_true(ngrid),zcdh_true(ngrid) REAL zu(ngrid,nlay),zv(ngrid,nlay) REAL zh(ngrid,nlay) REAL ztsrf2(ngrid) REAL z1(ngrid),z2(ngrid) REAL za(ngrid,nlay),zb(ngrid,nlay) REAL zb0(ngrid,nlay) REAL zc(ngrid,nlay),zd(ngrid,nlay) REAL zcst1 REAL zu2!, a REAL zcq(ngrid,nlay),zdq(ngrid,nlay) REAL evap(ngrid) REAL zcq0(ngrid),zdq0(ngrid) REAL zx_alf1(ngrid),zx_alf2(ngrid) LOGICAL firstcall SAVE firstcall LOGICAL lastcall ! variables added for CO2 condensation ! ------------------------------------ REAL hh !, zhcond(ngrid,nlay) ! REAL latcond,tcond1mb ! REAL acond,bcond ! SAVE acond,bcond ! DATA latcond,tcond1mb/5.9e5,136.27/ ! Tracers ! ------- INTEGER iq REAL zq(ngrid,nlay,nq) REAL zq1temp(ngrid) REAL rho(ngrid) ! near-surface air density REAL qsat(ngrid) DATA firstcall/.true./ REAL kmixmin ! Variables added for implicit latent heat inclusion ! -------------------------------------------------- real latconst, dqsat(ngrid), qsat_temp1, qsat_temp2 real z1_Tdry(ngrid), z2_Tdry(ngrid) real z1_T(ngrid), z2_T(ngrid) real zb_T(ngrid) real zc_T(ngrid,nlay) real zd_T(ngrid,nlay) real lat1(ngrid), lat2(ngrid) real surfh2otot logical surffluxdiag integer isub ! sub-loop for precision integer ivap, iice ! also make liq for clarity on surface... save ivap, iice real, parameter :: karman=0.4 real cd0, roughratio logical forceWC real masse, Wtot, Wdiff real dqsdif_total(ngrid) real zq0(ngrid) forceWC=.true. ! forceWC=.false. ! Coherence test ! -------------- IF (firstcall) THEN ! To compute: Tcond= 1./(bcond-acond*log(.0095*p)) (p in pascal) ! bcond=1./tcond1mb ! acond=r/latcond ! PRINT*,'In vdifc: Tcond(P=1mb)=',tcond1mb,' Lcond=',latcond ! PRINT*,' acond,bcond',acond,bcond if(water)then ! iliq=igcm_h2o_vap ivap=igcm_h2o_vap iice=igcm_h2o_ice ! simply to make the code legible ! to be generalised later endif firstcall=.false. ENDIF !----------------------------------------------------------------------- ! 1. Initialisation ! ----------------- nlev=nlay+1 ! Calculate rho*dz and dt*rho/dz=dt*rho**2 g/dp ! with rho=p/RT=p/ (R Theta) (p/ps)**kappa ! --------------------------------------------- DO ilay=1,nlay DO ig=1,ngrid za(ig,ilay)=(pplev(ig,ilay)-pplev(ig,ilay+1))/g ENDDO ENDDO zcst1=4.*g*ptimestep/(R*R) DO ilev=2,nlev-1 DO ig=1,ngrid zb0(ig,ilev)=pplev(ig,ilev)* s (pplev(ig,1)/pplev(ig,ilev))**rcp / s (ph(ig,ilev-1)+ph(ig,ilev)) zb0(ig,ilev)=zcst1*zb0(ig,ilev)*zb0(ig,ilev)/ s (pplay(ig,ilev-1)-pplay(ig,ilev)) ENDDO ENDDO DO ig=1,ngrid zb0(ig,1)=ptimestep*pplev(ig,1)/(R*ptsrf(ig)) ENDDO dqsdif_total(:)=0.0 !----------------------------------------------------------------------- ! 2. Add the physical tendencies computed so far ! ---------------------------------------------- DO ilev=1,nlay DO ig=1,ngrid zu(ig,ilev)=pu(ig,ilev)+pdufi(ig,ilev)*ptimestep zv(ig,ilev)=pv(ig,ilev)+pdvfi(ig,ilev)*ptimestep zh(ig,ilev)=ph(ig,ilev)+pdhfi(ig,ilev)*ptimestep ENDDO ENDDO if(tracer) then DO iq =1, nq DO ilev=1,nlay DO ig=1,ngrid zq(ig,ilev,iq)=pq(ig,ilev,iq) + & pdqfi(ig,ilev,iq)*ptimestep ENDDO ENDDO ENDDO end if !----------------------------------------------------------------------- ! 3. Turbulence scheme ! -------------------- ! ! Source of turbulent kinetic energy at the surface ! ------------------------------------------------- ! Formula is Cd_0 = (karman / log[1+z1/z0])^2 DO ig=1,ngrid roughratio = 1.E+0 + pzlay(ig,1)/pz0 cd0 = karman/log(roughratio) cd0 = cd0*cd0 zcdv_true(ig) = cd0 zcdh_true(ig) = cd0 if (nosurf) then zcdv_true(ig) = 0. !! disable sensible momentum flux zcdh_true(ig) = 0. !! disable sensible heat flux endif ENDDO DO ig=1,ngrid zu2=pu(ig,1)*pu(ig,1)+pv(ig,1)*pv(ig,1) zcdv(ig)=zcdv_true(ig)*sqrt(zu2) zcdh(ig)=zcdh_true(ig)*sqrt(zu2) ENDDO ! Turbulent diffusion coefficients in the boundary layer ! ------------------------------------------------------ call vdif_kc(ngrid,nlay,ptimestep,g,pzlev,pzlay & ,pu,pv,ph,zcdv_true & ,pq2,zkv,zkh) ! Adding eddy mixing to mimic 3D general circulation in 1D ! R. Wordsworth & F. Forget (2010) if ((ngrid.eq.1)) then kmixmin = 1.0e-2 ! minimum eddy mix coeff in 1D do ilev=1,nlay do ig=1,ngrid !zkh(ig,ilev) = 1.0 zkh(ig,ilev) = max(kmixmin,zkh(ig,ilev)) zkv(ig,ilev) = max(kmixmin,zkv(ig,ilev)) end do end do end if !----------------------------------------------------------------------- ! 4. Implicit inversion of u ! -------------------------- ! u(t+1) = u(t) + dt * {(du/dt)phys}(t) + dt * {(du/dt)difv}(t+1) ! avec ! /zu/ = u(t) + dt * {(du/dt)phys}(t) (voir paragraphe 2.) ! et ! dt * {(du/dt)difv}(t+1) = dt * {(d/dz)[ Ku (du/dz) ]}(t+1) ! donc les entrees sont /zcdv/ pour la condition a la limite sol ! et /zkv/ = Ku CALL multipl((nlay-1)*ngrid,zkv(1,2),zb0(1,2),zb(1,2)) CALL multipl(ngrid,zcdv,zb0,zb) DO ig=1,ngrid z1(ig)=1./(za(ig,nlay)+zb(ig,nlay)) zc(ig,nlay)=za(ig,nlay)*zu(ig,nlay)*z1(ig) zd(ig,nlay)=zb(ig,nlay)*z1(ig) ENDDO DO ilay=nlay-1,1,-1 DO ig=1,ngrid z1(ig)=1./(za(ig,ilay)+zb(ig,ilay)+ $ zb(ig,ilay+1)*(1.-zd(ig,ilay+1))) zc(ig,ilay)=(za(ig,ilay)*zu(ig,ilay)+ $ zb(ig,ilay+1)*zc(ig,ilay+1))*z1(ig) zd(ig,ilay)=zb(ig,ilay)*z1(ig) ENDDO ENDDO DO ig=1,ngrid zu(ig,1)=zc(ig,1) ENDDO DO ilay=2,nlay DO ig=1,ngrid zu(ig,ilay)=zc(ig,ilay)+zd(ig,ilay)*zu(ig,ilay-1) ENDDO ENDDO !----------------------------------------------------------------------- ! 5. Implicit inversion of v ! -------------------------- ! v(t+1) = v(t) + dt * {(dv/dt)phys}(t) + dt * {(dv/dt)difv}(t+1) ! avec ! /zv/ = v(t) + dt * {(dv/dt)phys}(t) (voir paragraphe 2.) ! et ! dt * {(dv/dt)difv}(t+1) = dt * {(d/dz)[ Kv (dv/dz) ]}(t+1) ! donc les entrees sont /zcdv/ pour la condition a la limite sol ! et /zkv/ = Kv DO ig=1,ngrid z1(ig)=1./(za(ig,nlay)+zb(ig,nlay)) zc(ig,nlay)=za(ig,nlay)*zv(ig,nlay)*z1(ig) zd(ig,nlay)=zb(ig,nlay)*z1(ig) ENDDO DO ilay=nlay-1,1,-1 DO ig=1,ngrid z1(ig)=1./(za(ig,ilay)+zb(ig,ilay)+ $ zb(ig,ilay+1)*(1.-zd(ig,ilay+1))) zc(ig,ilay)=(za(ig,ilay)*zv(ig,ilay)+ $ zb(ig,ilay+1)*zc(ig,ilay+1))*z1(ig) zd(ig,ilay)=zb(ig,ilay)*z1(ig) ENDDO ENDDO DO ig=1,ngrid zv(ig,1)=zc(ig,1) ENDDO DO ilay=2,nlay DO ig=1,ngrid zv(ig,ilay)=zc(ig,ilay)+zd(ig,ilay)*zv(ig,ilay-1) ENDDO ENDDO !---------------------------------------------------------------------------- ! 6. Implicit inversion of h, not forgetting the coupling with the ground ! h(t+1) = h(t) + dt * {(dh/dt)phys}(t) + dt * {(dh/dt)difv}(t+1) ! avec ! /zh/ = h(t) + dt * {(dh/dt)phys}(t) (voir paragraphe 2.) ! et ! dt * {(dh/dt)difv}(t+1) = dt * {(d/dz)[ Kh (dh/dz) ]}(t+1) ! donc les entrees sont /zcdh/ pour la condition de raccord au sol ! et /zkh/ = Kh ! Using the wind modified by friction for lifting and sublimation ! --------------------------------------------------------------- DO ig=1,ngrid zu2 = zu(ig,1)*zu(ig,1)+zv(ig,1)*zv(ig,1) zcdv(ig) = zcdv_true(ig)*sqrt(zu2) zcdh(ig) = zcdh_true(ig)*sqrt(zu2) ENDDO CALL multipl((nlay-1)*ngrid,zkh(1,2),zb0(1,2),zb(1,2)) CALL multipl(ngrid,zcdh,zb0,zb) DO ig=1,ngrid z1(ig)=1./(za(ig,nlay)+zb(ig,nlay)) zc(ig,nlay)=za(ig,nlay)*zh(ig,nlay)*z1(ig) zd(ig,nlay)=zb(ig,nlay)*z1(ig) ENDDO DO ilay=nlay-1,2,-1 DO ig=1,ngrid z1(ig)=1./(za(ig,ilay)+zb(ig,ilay)+ & zb(ig,ilay+1)*(1.-zd(ig,ilay+1))) zc(ig,ilay)=(za(ig,ilay)*zh(ig,ilay)+ & zb(ig,ilay+1)*zc(ig,ilay+1))*z1(ig) zd(ig,ilay)=zb(ig,ilay)*z1(ig) ENDDO ENDDO DO ig=1,ngrid z1(ig)=1./(za(ig,1)+zb(ig,1)+ & zb(ig,2)*(1.-zd(ig,2))) zc(ig,1)=(za(ig,1)*zh(ig,1)+ & zb(ig,2)*zc(ig,2))*z1(ig) zd(ig,1)=zb(ig,1)*z1(ig) ENDDO ! Calculate (d Planck / dT) at the interface temperature ! ------------------------------------------------------ z4st=4.0*sigma*ptimestep DO ig=1,ngrid zdplanck(ig)=z4st*pemis(ig)*ptsrf(ig)*ptsrf(ig)*ptsrf(ig) ENDDO ! Calculate temperature tendency at the interface (dry case) ! ---------------------------------------------------------- ! Sum of fluxes at interface at time t + \delta t gives change in T: ! radiative fluxes ! turbulent convective (sensible) heat flux ! flux (if any) from subsurface if(.not.water) then DO ig=1,ngrid z1(ig) = pcapcal(ig)*ptsrf(ig) + cpp*zb(ig,1)*zc(ig,1) & + zdplanck(ig)*ptsrf(ig) + pfluxsrf(ig)*ptimestep z2(ig) = pcapcal(ig) + cpp*zb(ig,1)*(1.-zd(ig,1)) & +zdplanck(ig) ztsrf2(ig) = z1(ig) / z2(ig) pdtsrf(ig) = (ztsrf2(ig) - ptsrf(ig))/ptimestep zh(ig,1) = zc(ig,1) + zd(ig,1)*ztsrf2(ig) ENDDO ! Recalculate temperature to top of atmosphere, starting from ground ! ------------------------------------------------------------------ DO ilay=2,nlay DO ig=1,ngrid hh = zh(ig,ilay-1) zh(ig,ilay)=zc(ig,ilay)+zd(ig,ilay)*hh ENDDO ENDDO endif ! not water !----------------------------------------------------------------------- ! TRACERS (no vapour) ! ------- if(tracer) then ! Calculate vertical flux from the bottom to the first layer (dust) ! ----------------------------------------------------------------- do ig=1,ngrid rho(ig) = zb0(ig,1) /ptimestep end do call zerophys(ngrid*nq,pdqsdif) ! Implicit inversion of q ! ----------------------- do iq=1,nq if (iq.ne.igcm_h2o_vap) then DO ig=1,ngrid z1(ig)=1./(za(ig,nlay)+zb(ig,nlay)) zcq(ig,nlay)=za(ig,nlay)*zq(ig,nlay,iq)*z1(ig) zdq(ig,nlay)=zb(ig,nlay)*z1(ig) ENDDO DO ilay=nlay-1,2,-1 DO ig=1,ngrid z1(ig)=1./(za(ig,ilay)+zb(ig,ilay)+ & zb(ig,ilay+1)*(1.-zdq(ig,ilay+1))) zcq(ig,ilay)=(za(ig,ilay)*zq(ig,ilay,iq)+ & zb(ig,ilay+1)*zcq(ig,ilay+1))*z1(ig) zdq(ig,ilay)=zb(ig,ilay)*z1(ig) ENDDO ENDDO if ((water).and.(iq.eq.iice)) then ! special case for water ice tracer: do not include ! h2o ice tracer from surface (which is set when handling ! h2o vapour case (see further down). ! zb(ig,1)=0 if iq ne ivap DO ig=1,ngrid z1(ig)=1./(za(ig,1)+ & zb(ig,2)*(1.-zdq(ig,2))) zcq(ig,1)=(za(ig,1)*zq(ig,1,iq)+ & zb(ig,2)*zcq(ig,2))*z1(ig) ENDDO else ! general case DO ig=1,ngrid z1(ig)=1./(za(ig,1)+ & zb(ig,2)*(1.-zdq(ig,2))) zcq(ig,1)=(za(ig,1)*zq(ig,1,iq)+ & zb(ig,2)*zcq(ig,2) & +(-pdqsdif(ig,iq))*ptimestep)*z1(ig) ! tracer flux from surface ! currently pdqsdif always zero here, ! so last line is superfluous enddo endif ! of if (water.and.(iq.eq.igcm_h2o_ice)) ! Starting upward calculations for simple tracer mixing (e.g., dust) do ig=1,ngrid zq(ig,1,iq)=zcq(ig,1) end do do ilay=2,nlay do ig=1,ngrid zq(ig,ilay,iq)=zcq(ig,ilay)+ $ zdq(ig,ilay)*zq(ig,ilay-1,iq) end do end do endif ! if (iq.ne.igcm_h2o_vap) ! Calculate temperature tendency including latent heat term ! and assuming an infinite source of water on the ground ! ------------------------------------------------------------------ if (water.and.(iq.eq.igcm_h2o_vap)) then ! compute evaporation efficiency do ig = 1, ngrid if(nint(rnat(ig)).eq.1)then dryness(ig)=pqsurf(ig,ivap)+pqsurf(ig,iice) dryness(ig)=MIN(1.,2*dryness(ig)/mx_eau_sol) dryness(ig)=MAX(0.,dryness(ig)) endif enddo do ig=1,ngrid ! Calculate the value of qsat at the surface (water) call watersat(ptsrf(ig),pplev(ig,1),qsat(ig)) call watersat(ptsrf(ig)-0.0001,pplev(ig,1),qsat_temp1) call watersat(ptsrf(ig)+0.0001,pplev(ig,1),qsat_temp2) dqsat(ig)=(qsat_temp2-qsat_temp1)/0.0002 ! calculate dQsat / dT by finite differences ! we cannot use the updated temperature value yet... enddo ! coefficients for q do ig=1,ngrid z1(ig)=1./(za(ig,nlay)+zb(ig,nlay)) zcq(ig,nlay)=za(ig,nlay)*zq(ig,nlay,iq)*z1(ig) zdq(ig,nlay)=zb(ig,nlay)*z1(ig) enddo do ilay=nlay-1,2,-1 do ig=1,ngrid z1(ig)=1./(za(ig,ilay)+zb(ig,ilay)+ $ zb(ig,ilay+1)*(1.-zdq(ig,ilay+1))) zcq(ig,ilay)=(za(ig,ilay)*zq(ig,ilay,iq)+ $ zb(ig,ilay+1)*zcq(ig,ilay+1))*z1(ig) zdq(ig,ilay)=zb(ig,ilay)*z1(ig) enddo enddo do ig=1,ngrid z1(ig)=1./(za(ig,1)+zb(ig,1)*dryness(ig)+ $ zb(ig,2)*(1.-zdq(ig,2))) zcq(ig,1)=(za(ig,1)*zq(ig,1,iq)+ $ zb(ig,2)*zcq(ig,2))*z1(ig) zdq(ig,1)=dryness(ig)*zb(ig,1)*z1(ig) enddo ! calculation of h0 and h1 do ig=1,ngrid zdq0(ig) = dqsat(ig) zcq0(ig) = qsat(ig)-dqsat(ig)*ptsrf(ig) z1(ig) = pcapcal(ig)*ptsrf(ig) +cpp*zb(ig,1)*zc(ig,1) & + zdplanck(ig)*ptsrf(ig) + pfluxsrf(ig)*ptimestep & + zb(ig,1)*dryness(ig)*RLVTT* & ((zdq(ig,1)-1.0)*zcq0(ig)+zcq(ig,1)) z2(ig) = pcapcal(ig) + cpp*zb(ig,1)*(1.-zd(ig,1)) & +zdplanck(ig) & +zb(ig,1)*dryness(ig)*RLVTT*zdq0(ig)* & (1.0-zdq(ig,1)) ztsrf2(ig) = z1(ig) / z2(ig) pdtsrf(ig) = (ztsrf2(ig) - ptsrf(ig))/ptimestep zh(ig,1) = zc(ig,1) + zd(ig,1)*ztsrf2(ig) enddo ! calculation of qs and q1 do ig=1,ngrid zq0(ig) = zcq0(ig)+zdq0(ig)*ztsrf2(ig) zq(ig,1,iq) = zcq(ig,1)+zdq(ig,1)*zq0(ig) enddo ! calculation of evaporation do ig=1,ngrid evap(ig)= zb(ig,1)*dryness(ig)*(zq(ig,1,ivap)-zq0(ig)) dqsdif_total(ig)=evap(ig) enddo ! recalculate temperature and q(vap) to top of atmosphere, starting from ground do ilay=2,nlay do ig=1,ngrid zq(ig,ilay,iq)=zcq(ig,ilay) & +zdq(ig,ilay)*zq(ig,ilay-1,iq) zh(ig,ilay)=zc(ig,ilay)+zd(ig,ilay)*zh(ig,ilay-1) end do end do do ig=1,ngrid ! -------------------------------------------------------------------------- ! On the ocean, if T > 0 C then the vapour tendency must replace the ice one ! The surface vapour tracer is actually liquid. To make things difficult. if (nint(rnat(ig)).eq.0) then ! unfrozen ocean pdqsdif(ig,ivap)=dqsdif_total(ig)/ptimestep pdqsdif(ig,iice)=0.0 elseif (nint(rnat(ig)).eq.1) then ! (continent) ! -------------------------------------------------------- ! Now check if we've taken too much water from the surface ! This can only occur on the continent ! If water is evaporating / subliming, we take it from ice before liquid ! -- is this valid?? if(dqsdif_total(ig).lt.0)then pdqsdif(ig,iice)=dqsdif_total(ig)/ptimestep pdqsdif(ig,iice)=max(-pqsurf(ig,iice)/ptimestep & ,pdqsdif(ig,iice)) endif ! sublimation only greater than qsurf(ice) ! ---------------------------------------- ! we just convert some liquid to vapour too ! if latent heats are the same, no big deal if (-dqsdif_total(ig).gt.pqsurf(ig,iice))then pdqsdif(ig,iice) = -pqsurf(ig,iice)/ptimestep ! removes all the ice! pdqsdif(ig,ivap) = dqsdif_total(ig)/ptimestep & - pdqsdif(ig,iice) ! take the remainder from the liquid instead pdqsdif(ig,ivap) = max(-pqsurf(ig,ivap)/ptimestep & ,pdqsdif(ig,ivap)) endif endif ! if (rnat.ne.1) ! If water vapour is condensing, we must decide whether it forms ice or liquid. if(dqsdif_total(ig).gt.0)then ! a bug was here! if(ztsrf2(ig).gt.T_h2O_ice_liq)then pdqsdif(ig,iice)=0.0 pdqsdif(ig,ivap)=dqsdif_total(ig)/ptimestep else pdqsdif(ig,iice)=dqsdif_total(ig)/ptimestep pdqsdif(ig,ivap)=0.0 endif endif end do ! of DO ig=1,ngrid endif ! if (water et iq=ivap) end do ! of do iq=1,nq endif ! traceur !----------------------------------------------------------------------- ! 8. Final calculation of the vertical diffusion tendencies ! ----------------------------------------------------------------- do ilev = 1, nlay do ig=1,ngrid pdudif(ig,ilev)=(zu(ig,ilev)- & (pu(ig,ilev)+pdufi(ig,ilev)*ptimestep))/ptimestep pdvdif(ig,ilev)=(zv(ig,ilev)- & (pv(ig,ilev)+pdvfi(ig,ilev)*ptimestep))/ptimestep hh = ph(ig,ilev)+pdhfi(ig,ilev)*ptimestep pdhdif(ig,ilev)=( zh(ig,ilev)- hh )/ptimestep enddo enddo DO ig=1,ngrid ! computing sensible heat flux (atm => surface) sensibFlux(ig)=cpp*zb(ig,1)/ptimestep*(zh(ig,1)-ztsrf2(ig)) ENDDO if (tracer) then do iq = 1, nq do ilev = 1, nlay do ig=1,ngrid pdqdif(ig,ilev,iq)=(zq(ig,ilev,iq)- & (pq(ig,ilev,iq)+pdqfi(ig,ilev,iq)*ptimestep))/ & ptimestep enddo enddo enddo if(water.and.forceWC)then ! force water conservation in model ! we calculate the difference and add it to the ground ! this is ugly and should be improved in the future do ig=1,ngrid Wtot=0.0 do ilay=1,nlay masse = (pplev(ig,ilay) - pplev(ig,ilay+1))/g ! Wtot=Wtot+masse*(zq(ig,ilay,iice)- ! & (pq(ig,ilay,iice)+pdqfi(ig,ilay,iice)*ptimestep)) Wtot=Wtot+masse*(zq(ig,ilay,ivap)- & (pq(ig,ilay,ivap)+pdqfi(ig,ilay,ivap)*ptimestep)) enddo Wdiff=Wtot/ptimestep+pdqsdif(ig,ivap)+pdqsdif(ig,iice) if(ztsrf2(ig).gt.T_h2O_ice_liq)then pdqsdif(ig,ivap)=pdqsdif(ig,ivap)-Wdiff else pdqsdif(ig,iice)=pdqsdif(ig,iice)-Wdiff endif enddo endif endif if(water)then call writediagfi(ngrid,'beta','Dryness coefficient',' ',2,dryness) endif ! if(lastcall)then ! if(ngrid.eq.1)then ! print*,'Saving k.out...' ! OPEN(12,file='k.out',form='formatted') ! DO ilay=1,nlay ! write(12,*) zkh(1,ilay), pplay(1,ilay) ! ENDDO ! CLOSE(12) ! endif ! endif return end