subroutine fluxes (is, ie, js, je) #if defined O_embm !======================================================================= ! calculate energy and moisture fluxes ! Note: evaporation and precipitation are in g cm-2 s-1 ! and humidities are in g g-1 ! for Thompson and Warren outgoing radiation (see: Thompson S.J., ! and S.G. Warren 'parameterization of outgoing ...'J. Atmos. Sci., ! 39, 2667-2680, 1982. !======================================================================= implicit none integer i, ie, iem1, imax, is, isp1, iter integer j, je, jem1, jmax, js, jsp1, maxit, n logical track real b00, b10, b20, b01, b11, b21, b02, b12, b22, b03, b13, b23 real delta, df, dt, dultnt, dulwr, dusens, emax, f, fb, ff, fg real fh, fl, fm, qair, qlnd, rhrh, sr, scrit, ssh, tair, teff real telev, tlnd, tlold, tol, tol2, ultnt, ulwr, usens, wspd real vcs, avg_sat, C2K include "size.h" include "param.h" include "pconst.h" include "stdunits.h" include "cembm.h" include "atm.h" include "csbc.h" # if defined O_ice_cpts && defined O_ice include "cpts.h" # endif include "ice.h" # if defined O_embm_vcs # include "tmngr.h" # endif include "veg.h" isp1 = is + 1 iem1 = ie - 1 jsp1 = js + 1 jem1 = je - 1 !----------------------------------------------------------------------- ! set appropriate constants !----------------------------------------------------------------------- fb = 0.94*rhoatm*cpatm maxit = 10 tol = 0.01 emax = 0.0 imax = 0 jmax = 0 scrit = 0.75*soilmax ff = rhoatm*vlocn C2K = 273.15 ! Thomson and Warren constants b00 = 2.3829382e2 b10 = -3.47968e1 b20 = 1.02790e1 b01 = 2.60065 b11 = -1.62064 b21 = 6.34856e-1 b02 = 4.40272e-3 b12 = -2.26092e-2 b22 = 1.12265e-2 b03 = -2.05237e-5 b13 = -9.67e-5 b23 = 5.62925e-5 tol2 = tol*2.0 # if defined O_embm_vcs vcs = 0.0 track = .true. avg_sat = 0. do n=1,ntrack_sat if (track_sat(n) .ge. 1.e10) track = .false. avg_sat = avg_sat + track_sat(n) enddo if (ntrack_sat .gt. 0) avg_sat = avg_sat/ntrack_sat if (track .and. relyr + year0 .ge. vcsyri) & vcs = (avg_sat - vcsref)*vcsfac # endif do j=jsp1,jem1 do i=isp1,iem1 !----------------------------------------------------------------------- ! set the incoming short wave !----------------------------------------------------------------------- # if defined O_sulphate_data_transient dnswr(i,j) = solins(i,j)*sbc(i,j,iaca)*pass & *max(c0, sbc(i,j,isca) - sulph(i,j,2)) # else dnswr(i,j) = solins(i,j)*sbc(i,j,iaca)*pass*sbc(i,j,isca) # endif !----------------------------------------------------------------------- ! set wind speed and effective elevated air temperature !----------------------------------------------------------------------- wspd = sbc(i,j,iws) telev = elev(i,j) # if defined O_landice_data & + hicel(i,j,2) # endif # if defined O_sealev || defined O_sealev_data & + elev_sealev(i,j) # endif teff = at(i,j,2,isat) & - telev*rlapse*rf1*exp(max(-1.,-telev/rf2)) !----------------------------------------------------------------------- ! calculate outgoing longwave radiation !----------------------------------------------------------------------- rhrh = rh(i,j)*rh(i,j) outlwr(i,j) = 1.0e3*(b00 + b10*rh(i,j) + b20*rhrh & + (b01 + b11*rh(i,j) + b21*rhrh)*teff & + (b02 + b12*rh(i,j) + b22*rhrh)*teff**2 & + (b03 + b13*rh(i,j) + b23*rhrh)*teff**3) # if defined O_carbon && defined O_carbon_co2_2d & - co2for*alog(at(i,j,2,ico2)/280.0) # else & - anthro # endif # if defined O_aggfor_data_transient & - aggfor + aggfor_os # endif # if defined O_embm_vcs & - vcs # endif tair = at(i,j,2,isat) - telev*rlapse if (tmsk(i,j) .ge. 0.5) then !----------------------------------------------------------------------- ! calculations only for ocean points !----------------------------------------------------------------------- dt = sbc(i,j,isst) - tair fg = dalt_o*wspd !----------------------------------------------------------------------- ! calculate evaporation or sublimation (ensure it is positive) !----------------------------------------------------------------------- ssh = cssh*exp(17.67*sbc(i,j,isst)/(sbc(i,j,isst) + 243.5)) evap(i,j) = max(c0, rhoatm*fg*(ssh - at(i,j,2,ishum))) upltnt(i,j) = vlocn*evap(i,j) !----------------------------------------------------------------------- ! calculate upward sensible heat flux !----------------------------------------------------------------------- upsens(i,j) = fb*fg*(dt) !----------------------------------------------------------------------- ! calculate upward longwave re-radiation !----------------------------------------------------------------------- uplwr(i,j) = esocn*(sbc(i,j,isst) + C2K)**4 & - esatm*(tair + C2K)**4 # if defined O_mtlm elseif (land_map(i,j) .ne. 0) then !---------------------------------------------------------------------- ! set fluxes over land from the land model !--------------------------------------------------------------------- upltnt(i,j) = 0.0 evap(i,j) = sbc(i,j,ievap) upsens(i,j) = sbc(i,j,isens) uplwr(i,j) = sbc(i,j,ilwr) # endif else !----------------------------------------------------------------------- ! calculations only for land points ! find land temperature by balancing the surface heat budget ! dwsr = ultnt + usens + ulwr ! using Newton's method: ! t(i+1) = t(i) - f(t(i))/df(t(i)) ! where: ! f(t(i)) = dwsr - ultnt - usens - ulwr ! -df(t(i)) = dultnt - dusens - dulwr !----------------------------------------------------------------------- tlnd = surf(i,j) tlold = tlnd fm = esatm*(tair + C2K)**4 fg = rhoatm ! calculate stomatal resistance # if defined O_crop_data sr = (1.-crops(i,j,2))*veg_rs(iveg(i,j)) & + crops(i,j,2)*veg_rs(icrops) dalt_v = veg_dalt(i,j) # else sr = veg_rs(iveg(i,j)) dalt_v = veg_dalt(iveg(i,j)) # endif ! add in aerodynamic resistance sr = sr + 1.0/(dalt_v*wspd + epsln) ! set beta parameter for calculating actual evaporation fh = min(max(c0+epsln, (soilm(i,j,lf)/soilmax)**(0.25)),c1) ! set coefficients for latent heat (fl) and evaporation (fg) fl = fh*ff/(sr) fg = fh*fg/(sr) dusens = fb*dalt_v*wspd !----------------------------------------------------------------------- ! start loop for all land grid points !----------------------------------------------------------------------- qair = rh(i,j)*cssh*exp(17.67*tair/(tair + 243.5)) iter = 0 delta = tol2 do while (abs(delta) .gt. tol .and. iter .le. maxit) iter = iter + 1 qlnd = cssh*exp(17.67*tlnd/(tlnd + 243.5)) if (qlnd .gt. qair) then ultnt = fl*(qlnd - qair) dultnt = fl*qlnd*17.67*243.5/(tlnd + 243.5)**2 else ultnt = 0.0 dultnt = 0.0 endif usens = dusens*(tlnd - tair) ulwr = eslnd*(tlnd + C2K)**4 - fm dulwr = 4.0*eslnd*(tlnd + C2K)**3 f = dnswr(i,j) - ultnt - usens - ulwr df = dultnt + dusens + dulwr delta = f/df tlnd = tlnd + delta enddo if (iter .gt. maxit) then ! if not converged, set to last converged temperature if (abs(delta) .gt. emax) then emax = abs(delta) imax = i jmax = j tlnd = tlold endif endif !----------------------------------------------------------------------- ! calculate fluxes on land !----------------------------------------------------------------------- surf(i,j) = tlnd qlnd = cssh*exp(17.67*tlnd/(tlnd + 243.5)) evap(i,j) = max(c0, fg*(qlnd - qair)) evap(i,j) = max(c0, min(soilm(i,j,lf)/dts, evap(i,j))) # if defined O_ice flux(i,j,ishum) = evap(i,j)*(1.0 - aice(i,j,2)) # else flux(i,j,ishum) = evap(i,j) # endif upltnt(i,j) = vlocn*evap(i,j) upsens(i,j) = dusens*(tlnd - tair) uplwr(i,j) = eslnd*(tlnd + C2K)**4 - fm ! ensure fluxes are balanced since land can't absorb error upsens(i,j) = dnswr(i,j) - upltnt(i,j) - uplwr(i,j) endif enddo enddo if (emax .gt. 0.0) write (stdout,*) & '==> Warning: land surface temperature not converging: ' &, 'emax, i, j, soilm:', emax, imax, jmax, soilm(imax,jmax,2) return end subroutine precipitate (is, ie, js, je) !======================================================================= ! calculate precipitation explicitly and update humidity !======================================================================= implicit none integer i, ie, iem1, is, isp1, j, je, jem1, js, jsp1, k, n, negq real fb, fc, qmax, rate, tair, teff, telev, soiltemp, pson, psot real ssh, tmp include "size.h" include "param.h" include "pconst.h" include "stdunits.h" include "scalar.h" include "cembm.h" include "atm.h" include "switch.h" include "csbc.h" # if defined O_ice_cpts && defined O_ice include "cpts.h" # endif include "ice.h" # if defined O_mtlm include "mtlm.h" real hs(imt,jmt) # endif data negq /0/ save negq if (eoyear) negq = 0 isp1 = is + 1 iem1 = ie - 1 jsp1 = js + 1 jem1 = je - 1 !----------------------------------------------------------------------- ! set appropriate constants !----------------------------------------------------------------------- fb = rhoatm*shq/dts fc = dts/rhosno ! maximum relative humidity after rain # if defined O_mtlm call unloadland (POINTS, LYING_SNOW, imt, jmt, land_map, hs) ! convert from kg/m2 to cm hs(:,:) = hs(:,:)*0.1/rhosno # endif precip(:,:) = 0. rh(:,:) = 0. k = 0 do j=jsp1,jem1 do i=isp1,iem1 !----------------------------------------------------------------------- ! check if specific humidity is greater than rhmax of saturation !----------------------------------------------------------------------- telev = elev(i,j) # if defined O_landice_data & + hicel(i,j,2) # endif # if defined O_sealev || defined O_sealev_data & + elev_sealev(i,j) # endif teff = at(i,j,2,isat) & - telev*rlapse*rf1*exp(max(-1.,-telev/rf2)) ssh = cssh*exp(17.67*teff/(teff + 243.5)) qmax = rhmax*ssh if (at(i,j,2,ishum) .gt. qmax) then tmp = fb*(at(i,j,2,ishum) - qmax) precip(i,j) = precip(i,j) + tmp at(i,j,2,ishum) = at(i,j,2,ishum) - tmp/fb rh(i,j) = rhmax endif rh(i,j) = at(i,j,2,ishum)/(ssh + epsln) rh(i,j) = max(c0, min(c1, rh(i,j))) !----------------------------------------------------------------------- ! calculate snowfall (hsno at tau was set in the ice model) !----------------------------------------------------------------------- ! tair may be adjusted by a snowfall offset temperature tsno tair = at(i,j,2,isat) - tsno - telev*rlapse psno(i,j) = 0.0 # if defined O_ice_cpts && defined O_ice # if defined O_mtlm hs(i,j) = hs(i,j) + hseff(i,j,idx,1) if (tair .le. c0 .and. hs(i,j) .lt. hsno_max) & psno(i,j) = min((hsno_max - hs(i,j))/fc, precip(i,j)) # else if (tair .le. c0 .and. hseff(i,j,idx,1) .lt. hsno_max) & psno(i,j) = min((hsno_max - hseff(i,j,idx,1))/fc &, precip(i,j)) # endif if (tmsk(i,j) .ge. 0.5) then ! only allow snow where there is sea ice psot = 0. do n=1,ncat pson = psno(i,j)*A(i,j,idx,n) psot = psot + pson hseff(i,j,idx,n) = hseff(i,j,idx,n) + fc*pson enddo psno(i,j) = psot if (addflxa) flux(i,j,ishum) = flux(i,j,ishum) & - dts*psno(i,j) # if defined O_mtlm elseif (land_map(i,j) .eq. 0) then # else else # endif hseff(i,j,idx,1) = hseff(i,j,idx,1) + fc*psno(i,j) endif # elif defined O_ice # if defined O_mtlm hs(i,j) = hs(i,j) + hsno(i,j,2) if (tair .le. c0 .and. hs(i,j) .lt. hsno_max) & psno(i,j) = min((hsno_max - hs(i,j))/fc, precip(i,j)) # else if (tair .le. c0 .and. hsno(i,j,2) .lt. hsno_max) & psno(i,j) = min((hsno_max - hsno(i,j,2))/fc, precip(i,j)) # endif if (tmsk(i,j) .ge. 0.5) then ! only allow snow where there is sea ice psno(i,j) = psno(i,j)*aice(i,j,2) hsno(i,j,2) = hsno(i,j,2) + fc*psno(i,j) if (addflxa) flux(i,j,ishum) = flux(i,j,ishum) & - dts*psno(i,j) # if defined O_mtlm elseif (land_map(i,j) .eq. 0) then # else else # endif hsno(i,j,2) = hsno(i,j,2) + fc*psno(i,j) endif # endif !----------------------------------------------------------------------- ! update soilm and allocate surplus soil moisture to runoff !----------------------------------------------------------------------- # if defined O_mtlm if (tmsk(i,j) .lt. 0.5 .and. land_map(i,j) .eq. 0) then # else if (tmsk(i,j) .lt. 0.5) then # endif flux(i,j,ishum) = flux(i,j,ishum) - precip(i,j) + psno(i,j) soiltemp = soilm(i,j,2) soilm(i,j,2) = soilm(i,j,lf) - dts*flux(i,j,ishum) soilm(i,j,2) = max(c0, soilm(i,j,2)) soilm(i,j,1) = soiltemp if (soilm(i,j,2) .gt. soilmax) then runoff(i,j) = (soilm(i,j,2) - soilmax)/dts soilm(i,j,2) = soilmax else runoff(i,j) = c0 endif endif enddo enddo call embmbc (psno) # if defined O_ice_cpts && defined O_ice call embmbc (hseff(1,1,idx,1)) # else call embmbc (hsno(1,1,2)) # endif return end subroutine co2forc !======================================================================= ! calculate global average CO2 forcing !======================================================================= # if !defined O_carbon_co2_2d implicit none real yr include "cembm.h" !----------------------------------------------------------------------- ! relative forcing from 280 ppmv (anthro) !----------------------------------------------------------------------- anthro = co2for*alog(co2ccn/280.0) # endif #endif return end