! $Id: readaerosol_optic_ecrad.F90 ! SUBROUTINE readaerosol_optic_ecrad(debut, aerosol_couple, ok_alw, ok_volcan, & flag_aerosol, flag_bc_internal_mixture, itap, rjourvrai, & pdtphys, pplay, paprs, t_seri, rhcl, presnivs, & tr_seri, mass_solu_aero, mass_solu_aero_pi) ! tau_aero, piz_aero, cg_aero, & ! tausum_aero, drytausum_aero, tau3d_aero ) ! This routine will : ! 1) recevie the aerosols(already read and interpolated) corresponding to flag_aerosol ! 2) calculate the optical properties for the aerosols ! USE dimphy USE aero_mod USE phys_local_var_mod, only: sconcso4,sconcno3,sconcoa,sconcbc,sconcss,sconcdust, & concso4,concno3,concoa,concbc,concss,concdust,loadso4,loadoa,loadbc,loadss,loaddust, & loadno3,load_tmp1,load_tmp2,load_tmp3,load_tmp4,load_tmp5,load_tmp6,load_tmp7, & load_tmp8,load_tmp9,load_tmp10,m_allaer USE infotrac_phy, ONLY: tracers, nqtot, nbtr USE YOMCST IMPLICIT NONE include "clesphys.h" ! Input arguments !**************************************************************************************** LOGICAL, INTENT(IN) :: debut LOGICAL, INTENT(IN) :: aerosol_couple LOGICAL, INTENT(IN) :: ok_alw LOGICAL, INTENT(IN) :: ok_volcan INTEGER, INTENT(IN) :: flag_aerosol LOGICAL, INTENT(IN) :: flag_bc_internal_mixture INTEGER, INTENT(IN) :: itap REAL, INTENT(IN) :: rjourvrai REAL, INTENT(IN) :: pdtphys REAL, DIMENSION(klon,klev), INTENT(IN) :: pplay REAL, DIMENSION(klon,klev+1), INTENT(IN) :: paprs REAL, DIMENSION(klon,klev), INTENT(IN) :: t_seri REAL, DIMENSION(klon,klev), INTENT(IN) :: rhcl ! humidite relative ciel clair REAL, DIMENSION(klev), INTENT(IN) :: presnivs REAL, DIMENSION(klon,klev,nbtr), INTENT(IN) :: tr_seri ! concentration tracer ! Output arguments !**************************************************************************************** REAL, DIMENSION(klon,klev), INTENT(OUT) :: mass_solu_aero ! Total mass for all soluble aerosols REAL, DIMENSION(klon,klev), INTENT(OUT) :: mass_solu_aero_pi ! -"- preindustrial values ! REAL, DIMENSION(klon,klev,2,NSW), INTENT(OUT) :: tau_aero ! Aerosol optical thickness ! REAL, DIMENSION(klon,klev,2,NSW), INTENT(OUT) :: piz_aero ! Single scattering albedo aerosol ! REAL, DIMENSION(klon,klev,2,NSW), INTENT(OUT) :: cg_aero ! asymmetry parameter aerosol ! REAL, DIMENSION(klon,nwave,naero_tot), INTENT(OUT) :: tausum_aero ! REAL, DIMENSION(klon,naero_tot), INTENT(OUT) :: drytausum_aero ! REAL, DIMENSION(klon,klev,nwave,naero_tot), INTENT(OUT) :: tau3d_aero ! Local variables !**************************************************************************************** REAL, DIMENSION(klon) :: aerindex ! POLDER aerosol index REAL, DIMENSION(klon,klev) :: sulfacc ! SO4 accumulation concentration [ug/m3] REAL, DIMENSION(klon,klev) :: sulfcoarse ! SO4 coarse concentration [ug/m3] REAL, DIMENSION(klon,klev) :: bcsol ! BC soluble concentration [ug/m3] REAL, DIMENSION(klon,klev) :: bcins ! BC insoluble concentration [ug/m3] REAL, DIMENSION(klon,klev) :: pomsol ! POM soluble concentration [ug/m3] REAL, DIMENSION(klon,klev) :: pomins ! POM insoluble concentration [ug/m3] REAL, DIMENSION(klon,klev) :: cidust ! DUST aerosol concentration [ug/m3] REAL, DIMENSION(klon,klev) :: sscoarse ! SS Coarse concentration [ug/m3] REAL, DIMENSION(klon,klev) :: sssupco ! SS Super Coarse concentration [ug/m3] REAL, DIMENSION(klon,klev) :: ssacu ! SS Acumulation concentration [ug/m3] REAL, DIMENSION(klon,klev) :: nitracc ! nitrate accumulation concentration [ug/m3] REAL, DIMENSION(klon,klev) :: nitrcoarse ! nitrate coarse concentration [ug/m3] REAL, DIMENSION(klon,klev) :: nitrinscoarse ! nitrate insoluble coarse concentration [ug/m3] REAL, DIMENSION(klon,klev) :: sulfacc_pi REAL, DIMENSION(klon,klev) :: sulfcoarse_pi REAL, DIMENSION(klon,klev) :: bcsol_pi REAL, DIMENSION(klon,klev) :: bcins_pi REAL, DIMENSION(klon,klev) :: pomsol_pi REAL, DIMENSION(klon,klev) :: pomins_pi REAL, DIMENSION(klon,klev) :: cidust_pi REAL, DIMENSION(klon,klev) :: sscoarse_pi REAL, DIMENSION(klon,klev) :: sssupco_pi REAL, DIMENSION(klon,klev) :: ssacu_pi REAL, DIMENSION(klon,klev) :: nitracc_pi REAL, DIMENSION(klon,klev) :: nitrcoarse_pi REAL, DIMENSION(klon,klev) :: nitrinscoarse_pi REAL, DIMENSION(klon,klev) :: pdel, zrho ! REAL, DIMENSION(klon,klev,naero_tot) :: m_allaer REAL, DIMENSION(klon,klev,naero_tot) :: m_allaer_pi !RAF integer :: id_ASBCM, id_ASPOMM, id_ASSO4M, id_ASMSAM, id_CSSO4M, id_CSMSAM, id_SSSSM integer :: id_CSSSM, id_ASSSM, id_CIDUSTM, id_AIBCM, id_AIPOMM, id_ASNO3M, id_CSNO3M, id_CINO3M INTEGER :: k, i, iq, itr !--air density zrho(:,:)=pplay(:,:)/t_seri(:,:)/RD !--kg/m3 !**************************************************************************************** ! 1) Get aerosol mass ! !**************************************************************************************** ! ! IF (aerosol_couple) THEN !--we get aerosols from tr_seri array from INCA ! !--copy fields from INCA tr_seri !--convert to ug m-3 unit for consistency with offline fields ! itr = 0 DO iq = 1,nqtot IF(.NOT. tracers(iq)%isInPhysics) CYCLE itr = itr+1 SELECT CASE(trim(tracers(iq)%name)) CASE ("ASBCM"); id_ASBCM = itr CASE ("ASPOMM"); id_ASPOMM = itr CASE ("ASSO4M"); id_ASSO4M = itr CASE ("ASMSAM"); id_ASMSAM = itr CASE ("CSSO4M"); id_CSSO4M = itr CASE ("CSMSAM"); id_CSMSAM = itr CASE ("SSSSM"); id_SSSSM = itr CASE ("CSSSM"); id_CSSSM = itr CASE ("ASSSM"); id_ASSSM = itr CASE ("CIDUSTM");id_CIDUSTM= itr CASE ("AIBCM"); id_AIBCM = itr CASE ("AIPOMM"); id_AIPOMM = itr CASE ("ASNO3M"); id_ASNO3M = itr CASE ("CSNO3M"); id_CSNO3M = itr CASE ("CINO3M"); id_CINO3M = itr END SELECT END DO bcsol(:,:) = tr_seri(:,:,id_ASBCM) *zrho(:,:)*1.e9 ! ASBCM pomsol(:,:) = tr_seri(:,:,id_ASPOMM) *zrho(:,:)*1.e9 ! ASPOMM sulfacc(:,:) = (tr_seri(:,:,id_ASSO4M)+tr_seri(:,:,id_ASMSAM))*zrho(:,:)*1.e9 ! ASSO4M (=SO4) + ASMSAM (=MSA) sulfcoarse(:,:) = (tr_seri(:,:,id_CSSO4M)+tr_seri(:,:,id_CSMSAM))*zrho(:,:)*1.e9 ! CSSO4M (=SO4) + CSMSAM (=MSA) sssupco(:,:) = tr_seri(:,:,id_SSSSM) *zrho(:,:)*1.e9 ! SSSSM sscoarse(:,:) = tr_seri(:,:,id_CSSSM) *zrho(:,:)*1.e9 ! CSSSM ssacu(:,:) = tr_seri(:,:,id_ASSSM) *zrho(:,:)*1.e9 ! ASSSM cidust(:,:) = tr_seri(:,:,id_CIDUSTM) *zrho(:,:)*1.e9 ! CIDUSTM bcins(:,:) = tr_seri(:,:,id_AIBCM) *zrho(:,:)*1.e9 ! AIBCM pomins(:,:) = tr_seri(:,:,id_AIPOMM) *zrho(:,:)*1.e9 ! AIPOMM nitracc(:,:) = tr_seri(:,:,id_ASNO3M) *zrho(:,:)*1.e9 ! ASNO3M nitrcoarse(:,:) = tr_seri(:,:,id_CSNO3M) *zrho(:,:)*1.e9 ! CSNO3M nitrinscoarse(:,:)= tr_seri(:,:,id_CINO3M) *zrho(:,:)*1.e9 ! CINO3M ! bcsol_pi(:,:) = 0.0 ! ASBCM pre-ind pomsol_pi(:,:) = 0.0 ! ASPOMM pre-ind sulfacc_pi(:,:) = 0.0 ! ASSO4M (=SO4) + ASMSAM (=MSA) pre-ind sulfcoarse_pi(:,:) = 0.0 ! CSSO4M (=SO4) + CSMSAM (=MSA) pre-ind sssupco_pi(:,:) = 0.0 ! SSSSM pre-ind sscoarse_pi(:,:) = 0.0 ! CSSSM pre-ind ssacu_pi(:,:) = 0.0 ! ASSSM pre-ind cidust_pi(:,:) = 0.0 ! CIDUSTM pre-ind bcins_pi(:,:) = 0.0 ! AIBCM pre-ind pomins_pi(:,:) = 0.0 ! AIPOMM pre-ind nitracc_pi(:,:) = 0.0 ! ASNO3M pre-ind nitrcoarse_pi(:,:) = 0.0 ! CSNO3M pre-ind nitrinscoarse_pi(:,:)= 0.0 ! CINO3M ! ELSE !--not aerosol_couple ! ! Read and interpolate sulfate IF ( flag_aerosol .EQ. 1 .OR. flag_aerosol .EQ. 6 .OR. flag_aerosol .EQ. 7 ) THEN CALL readaerosol_interp(id_ASSO4M_phy, itap, pdtphys, rjourvrai, debut, pplay, paprs, t_seri, sulfacc, sulfacc_pi,loadso4) ELSE sulfacc(:,:) = 0. ; sulfacc_pi(:,:) = 0. loadso4=0. ENDIF ! Read and interpolate bcsol and bcins IF ( flag_aerosol .EQ. 2 .OR. flag_aerosol .EQ. 6 .OR. flag_aerosol .EQ. 7 ) THEN ! Get bc aerosol distribution CALL readaerosol_interp(id_ASBCM_phy, itap, pdtphys, rjourvrai, debut, pplay, paprs, t_seri, bcsol, bcsol_pi, load_tmp1 ) CALL readaerosol_interp(id_AIBCM_phy, itap, pdtphys, rjourvrai, debut, pplay, paprs, t_seri, bcins, bcins_pi, load_tmp2 ) loadbc(:)=load_tmp1(:)+load_tmp2(:) ELSE bcsol(:,:) = 0. ; bcsol_pi(:,:) = 0. bcins(:,:) = 0. ; bcins_pi(:,:) = 0. loadbc=0. ENDIF ! Read and interpolate pomsol and pomins IF ( flag_aerosol .EQ. 3 .OR. flag_aerosol .EQ. 6 .OR. flag_aerosol .EQ. 7 ) THEN CALL readaerosol_interp(id_ASPOMM_phy, itap, pdtphys, rjourvrai, debut, pplay, paprs, t_seri, pomsol, pomsol_pi, load_tmp3) CALL readaerosol_interp(id_AIPOMM_phy, itap, pdtphys, rjourvrai, debut, pplay, paprs, t_seri, pomins, pomins_pi, load_tmp4) loadoa(:)=load_tmp3(:)+load_tmp4(:) ELSE pomsol(:,:) = 0. ; pomsol_pi(:,:) = 0. pomins(:,:) = 0. ; pomins_pi(:,:) = 0. loadoa=0. ENDIF ! Read and interpolate csssm, ssssm, assssm IF (flag_aerosol .EQ. 4 .OR. flag_aerosol .EQ. 6 .OR. flag_aerosol .EQ. 7 ) THEN CALL readaerosol_interp(id_SSSSM_phy ,itap, pdtphys,rjourvrai, & debut, pplay, paprs, t_seri, sssupco, sssupco_pi, load_tmp5) CALL readaerosol_interp(id_CSSSM_phy ,itap, pdtphys,rjourvrai, & debut, pplay, paprs, t_seri, sscoarse,sscoarse_pi, load_tmp6) CALL readaerosol_interp(id_ASSSM_phy ,itap, pdtphys,rjourvrai, & debut, pplay, paprs, t_seri, ssacu, ssacu_pi, load_tmp7) loadss(:)=load_tmp5(:)+load_tmp6(:)+load_tmp7(:) ELSE sscoarse(:,:) = 0. ; sscoarse_pi(:,:) = 0. ssacu(:,:) = 0. ; ssacu_pi(:,:) = 0. sssupco(:,:) = 0. ; sssupco_pi = 0. loadss=0. ENDIF ! Read and interpolate cidustm IF (flag_aerosol .EQ. 5 .OR. flag_aerosol .EQ. 6 .OR. flag_aerosol .EQ. 7 ) THEN CALL readaerosol_interp(id_CIDUSTM_phy, itap, pdtphys, rjourvrai, debut, pplay, paprs, t_seri, cidust, cidust_pi, loaddust) ELSE cidust(:,:) = 0. ; cidust_pi(:,:) = 0. loaddust=0. ENDIF ! ! Read and interpolate asno3m, csno3m, cino3m IF (flag_aerosol .EQ. 6 .OR. flag_aerosol .EQ. 7 ) THEN CALL readaerosol_interp(id_ASNO3M_phy, itap, pdtphys, rjourvrai, & debut, pplay, paprs, t_seri, nitracc, nitracc_pi, load_tmp8) CALL readaerosol_interp(id_CSNO3M_phy, itap, pdtphys, rjourvrai, & debut, pplay, paprs, t_seri, nitrcoarse, nitrcoarse_pi, load_tmp9) CALL readaerosol_interp(id_CINO3M_phy, itap, pdtphys, rjourvrai, & debut, pplay, paprs, t_seri, nitrinscoarse, nitrinscoarse_pi, load_tmp10) loadno3(:)=load_tmp8(:)+load_tmp9(:)+load_tmp10(:) ELSE nitracc(:,:) = 0.0 ; nitracc_pi(:,:) = 0.0 nitrcoarse(:,:) = 0.0 ; nitrcoarse_pi(:,:) = 0.0 nitrinscoarse(:,:) = 0.0 ; nitrinscoarse_pi(:,:)= 0.0 loadno3(:)=0.0 ENDIF ! ! CSSO4M is set to 0 as not reliable sulfcoarse(:,:) = 0.0 ! CSSO4M (=SO4) + CSMSAM (=MSA) sulfcoarse_pi(:,:) = 0.0 ! CSSO4M (=SO4) + CSMSAM (=MSA) pre-ind ENDIF !--not aerosol_couple ! ! Store all aerosols mixing ratios in one variable for radiation scheme (unit kg/kg for ECRAD) ! present-day values m_allaer(:,:,id_ASBCM_phy) = bcsol(:,:) /1.e9/zrho(:,:) ! ASBCM m_allaer(:,:,id_ASPOMM_phy) = pomsol(:,:) /1.e9/zrho(:,:) ! ASPOMM m_allaer(:,:,id_ASSO4M_phy) = sulfacc(:,:) /1.e9/zrho(:,:) ! ASSO4M (= SO4) m_allaer(:,:,id_CSSO4M_phy) = sulfcoarse(:,:) /1.e9/zrho(:,:) ! CSSO4M m_allaer(:,:,id_SSSSM_phy) = sssupco(:,:) /1.e9/zrho(:,:) ! SSSSM m_allaer(:,:,id_CSSSM_phy) = sscoarse(:,:) /1.e9/zrho(:,:) ! CSSSM m_allaer(:,:,id_ASSSM_phy) = ssacu(:,:) /1.e9/zrho(:,:) ! ASSSM m_allaer(:,:,id_CIDUSTM_phy)= cidust(:,:) /1.e9/zrho(:,:) ! CIDUSTM m_allaer(:,:,id_AIBCM_phy) = bcins(:,:) /1.e9/zrho(:,:) ! AIBCM m_allaer(:,:,id_ASNO3M_phy) = nitracc(:,:) /1.e9/zrho(:,:) ! ASNO3M m_allaer(:,:,id_CSNO3M_phy) = nitrcoarse(:,:) /1.e9/zrho(:,:) ! CSNO3M m_allaer(:,:,id_CINO3M_phy) = nitrinscoarse(:,:)/1.e9/zrho(:,:) ! CINO3M m_allaer(:,:,id_AIPOMM_phy) = pomins(:,:) /1.e9/zrho(:,:) ! AIPOMM m_allaer(:,:,id_STRAT_phy) = 0.0 ! pre-industrial (pi) values m_allaer_pi(:,:,id_ASBCM_phy) = bcsol_pi(:,:) /1.e9/zrho(:,:) ! ASBCM pre-ind m_allaer_pi(:,:,id_ASPOMM_phy) = pomsol_pi(:,:) /1.e9/zrho(:,:) ! ASPOMM pre-ind m_allaer_pi(:,:,id_ASSO4M_phy) = sulfacc_pi(:,:) /1.e9/zrho(:,:) ! ASSO4M (= SO4) pre-ind m_allaer_pi(:,:,id_CSSO4M_phy) = sulfcoarse_pi(:,:) /1.e9/zrho(:,:) ! CSSO4M pre-ind m_allaer_pi(:,:,id_SSSSM_phy) = sssupco_pi(:,:) /1.e9/zrho(:,:) ! SSSSM pre-ind m_allaer_pi(:,:,id_CSSSM_phy) = sscoarse_pi(:,:) /1.e9/zrho(:,:) ! CSSSM pre-ind m_allaer_pi(:,:,id_ASSSM_phy) = ssacu_pi(:,:) /1.e9/zrho(:,:) ! ASSSM pre-ind m_allaer_pi(:,:,id_CIDUSTM_phy)= cidust_pi(:,:) /1.e9/zrho(:,:) ! CIDUSTM pre-ind m_allaer_pi(:,:,id_AIBCM_phy) = bcins_pi(:,:) /1.e9/zrho(:,:) ! AIBCM pre-ind m_allaer_pi(:,:,id_ASNO3M_phy) = nitracc_pi(:,:) /1.e9/zrho(:,:) ! ASNO3M pre-ind m_allaer_pi(:,:,id_CSNO3M_phy) = nitrcoarse_pi(:,:) /1.e9/zrho(:,:) ! CSNO3M pre-ind m_allaer_pi(:,:,id_CINO3M_phy) = nitrinscoarse_pi(:,:)/1.e9/zrho(:,:) ! CINO3M pre-ind m_allaer_pi(:,:,id_AIPOMM_phy) = pomins_pi(:,:) /1.e9/zrho(:,:) ! AIPOMM pre-ind m_allaer_pi(:,:,id_STRAT_phy) = 0.0 ! ! Calculate the total mass of all soluble aersosols (in unit ug /m3) ! to be revisited for AR6 mass_solu_aero(:,:) = sulfacc(:,:) + bcsol(:,:) + pomsol(:,:) + nitracc(:,:) + ssacu(:,:) mass_solu_aero_pi(:,:) = sulfacc_pi(:,:) + bcsol_pi(:,:) + pomsol_pi(:,:) + nitracc_pi(:,:) + ssacu_pi(:,:) !**************************************************************************************** ! 2) Calculate optical properties for the aerosols ! !**************************************************************************************** DO k = 1, klev DO i = 1, klon pdel(i,k) = paprs(i,k) - paprs (i,k+1) ENDDO ENDDO ! Diagnostics calculation for CMIP5 protocol unit (in unit kg/m3) sconcso4(:) =m_allaer(:,1,id_ASSO4M_phy)*1.e-9 sconcno3(:) =(m_allaer(:,1,id_ASNO3M_phy)+m_allaer(:,1,id_CSNO3M_phy)+m_allaer(:,1,id_CINO3M_phy))*1.e-9 sconcoa(:) =(m_allaer(:,1,id_ASPOMM_phy)+m_allaer(:,1,id_AIPOMM_phy))*1.e-9 sconcbc(:) =(m_allaer(:,1,id_ASBCM_phy)+m_allaer(:,1,id_AIBCM_phy))*1.e-9 sconcss(:) =(m_allaer(:,1,id_ASSSM_phy)+m_allaer(:,1,id_CSSSM_phy)+m_allaer(:,1,id_SSSSM_phy))*1.e-9 sconcdust(:) =m_allaer(:,1,id_CIDUSTM_phy)*1.e-9 concso4(:,:) =m_allaer(:,:,id_ASSO4M_phy)*1.e-9 concno3(:,:) =(m_allaer(:,:,id_ASNO3M_phy)+m_allaer(:,:,id_CSNO3M_phy)+m_allaer(:,:,id_CINO3M_phy))*1.e-9 concoa(:,:) =(m_allaer(:,:,id_ASPOMM_phy)+m_allaer(:,:,id_AIPOMM_phy))*1.e-9 concbc(:,:) =(m_allaer(:,:,id_ASBCM_phy)+m_allaer(:,:,id_AIBCM_phy))*1.e-9 concss(:,:) =(m_allaer(:,:,id_ASSSM_phy)+m_allaer(:,:,id_CSSSM_phy)+m_allaer(:,:,id_SSSSM_phy))*1.e-9 concdust(:,:)=m_allaer(:,:,id_CIDUSTM_phy)*1.e-9 END SUBROUTINE readaerosol_optic_ecrad