[222] | 1 | subroutine callcorrk(ngrid,nlayer,pq,nq,qsurf, & |
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| 2 | albedo,emis,mu0,pplev,pplay,pt, & |
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| 3 | tsurf,fract,dist_star,aerosol,muvar, & |
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| 4 | dtlw,dtsw,fluxsurf_lw, & |
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| 5 | fluxsurf_sw,fluxtop_lw,fluxabs_sw,fluxtop_dn, & |
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| 6 | OLR_nu,OSR_nu, & |
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| 7 | tau_col,cloudfrac,totcloudfrac, & |
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| 8 | clearsky,firstcall,lastcall) |
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| 9 | |
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| 10 | use radinc_h |
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| 11 | use radcommon_h |
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| 12 | use watercommon_h |
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| 13 | use datafile_mod, only: datadir |
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[227] | 14 | ! use ioipsl_getincom |
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| 15 | use ioipsl_getincom_p |
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[222] | 16 | use gases_h |
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| 17 | use radii_mod, only : su_aer_radii,co2_reffrad,h2o_reffrad,dust_reffrad,h2so4_reffrad,back2lay_reffrad |
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| 18 | use aerosol_mod, only : iaero_co2,iaero_h2o,iaero_dust,iaero_h2so4, iaero_back2lay |
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| 19 | USE tracer_h |
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| 20 | |
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| 21 | implicit none |
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| 22 | |
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| 23 | !================================================================== |
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| 24 | ! |
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| 25 | ! Purpose |
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| 26 | ! ------- |
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| 27 | ! Solve the radiative transfer using the correlated-k method for |
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| 28 | ! the gaseous absorption and the Toon et al. (1989) method for |
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| 29 | ! scatttering due to aerosols. |
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| 30 | ! |
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| 31 | ! Authors |
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| 32 | ! ------- |
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| 33 | ! Emmanuel 01/2001, Forget 09/2001 |
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| 34 | ! Robin Wordsworth (2009) |
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| 35 | ! |
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| 36 | !================================================================== |
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| 37 | |
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[227] | 38 | !#include "dimphys.h" |
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[222] | 39 | #include "comcstfi.h" |
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| 40 | #include "callkeys.h" |
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| 41 | |
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| 42 | !----------------------------------------------------------------------- |
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| 43 | ! Declaration of the arguments (INPUT - OUTPUT) on the LMD GCM grid |
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| 44 | ! Layer #1 is the layer near the ground. |
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[227] | 45 | ! Layer #nlayer is the layer at the top. |
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[222] | 46 | |
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| 47 | INTEGER,INTENT(IN) :: ngrid ! number of atmospheric columns |
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| 48 | INTEGER,INTENT(IN) :: nlayer ! number of atmospheric layers |
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| 49 | REAL,INTENT(IN) :: pq(ngrid,nlayer,nq) ! tracers (.../kg_of_air) |
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| 50 | integer,intent(in) :: nq ! number of tracers |
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| 51 | REAL,INTENT(IN) :: qsurf(ngrid,nq) ! tracer on surface (kg.m-2) |
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| 52 | REAL,INTENT(IN) :: albedo(ngrid) ! SW albedo |
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| 53 | REAL,INTENT(IN) :: emis(ngrid) ! LW emissivity |
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| 54 | real,intent(in) :: mu0(ngrid) ! cosine of sun incident angle |
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[227] | 55 | REAL,INTENT(IN) :: pplev(ngrid,nlayer+1) ! inter-layer pressure (Pa) |
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| 56 | REAL,INTENT(IN) :: pplay(ngrid,nlayer) ! mid-layer pressure (Pa) |
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| 57 | REAL,INTENT(IN) :: pt(ngrid,nlayer) ! air temperature (K) |
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[222] | 58 | REAL,INTENT(IN) :: tsurf(ngrid) ! surface temperature (K) |
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| 59 | REAL,INTENT(IN) :: fract(ngrid) ! fraction of day |
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| 60 | REAL,INTENT(IN) :: dist_star ! distance star-planet (AU) |
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[227] | 61 | REAL,INTENT(OUT) :: aerosol(ngrid,nlayer,naerkind) ! aerosol tau (kg/kg) |
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| 62 | real,intent(in) :: muvar(ngrid,nlayer+1) |
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| 63 | REAL,INTENT(OUT) :: dtlw(ngrid,nlayer) ! heating rate (K/s) due to LW |
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| 64 | REAL,INTENT(OUT) :: dtsw(ngrid,nlayer) ! heating rate (K/s) due to SW |
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[222] | 65 | REAL,INTENT(OUT) :: fluxsurf_lw(ngrid) ! incident LW flux to surf (W/m2) |
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| 66 | REAL,INTENT(OUT) :: fluxsurf_sw(ngrid) ! incident SW flux to surf (W/m2) |
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| 67 | REAL,INTENT(OUT) :: fluxtop_lw(ngrid) ! outgoing LW flux to space (W/m2) |
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| 68 | REAL,INTENT(OUT) :: fluxabs_sw(ngrid) ! SW flux absorbed by planet (W/m2) |
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| 69 | REAL,INTENT(OUT) :: fluxtop_dn(ngrid) ! incident top of atmosphere SW flux (W/m2) |
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| 70 | REAL,INTENT(OUT) :: OLR_nu(ngrid,L_NSPECTI)! Outgoing LW radition in each band (Normalized to the band width (W/m2/cm-1) |
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| 71 | REAL,INTENT(OUT) :: OSR_nu(ngrid,L_NSPECTV)! Outgoing SW radition in each band (Normalized to the band width (W/m2/cm-1) |
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| 72 | REAL,INTENT(OUT) :: tau_col(ngrid) ! diagnostic from aeropacity |
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| 73 | ! for H2O cloud fraction in aeropacity |
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[227] | 74 | real,intent(in) :: cloudfrac(ngrid,nlayer) |
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[222] | 75 | real,intent(out) :: totcloudfrac(ngrid) |
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| 76 | logical,intent(in) :: clearsky |
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| 77 | logical,intent(in) :: firstcall ! signals first call to physics |
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| 78 | logical,intent(in) :: lastcall ! signals last call to physics |
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| 79 | |
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| 80 | ! Globally varying aerosol optical properties on GCM grid |
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| 81 | ! Not needed everywhere so not in radcommon_h |
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[227] | 82 | REAL :: QVISsQREF3d(ngrid,nlayer,L_NSPECTV,naerkind) |
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| 83 | REAL :: omegaVIS3d(ngrid,nlayer,L_NSPECTV,naerkind) |
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| 84 | REAL :: gVIS3d(ngrid,nlayer,L_NSPECTV,naerkind) |
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[222] | 85 | |
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[227] | 86 | REAL :: QIRsQREF3d(ngrid,nlayer,L_NSPECTI,naerkind) |
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| 87 | REAL :: omegaIR3d(ngrid,nlayer,L_NSPECTI,naerkind) |
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| 88 | REAL :: gIR3d(ngrid,nlayer,L_NSPECTI,naerkind) |
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[222] | 89 | |
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[227] | 90 | ! REAL :: omegaREFvis3d(ngrid,nlayer,naerkind) |
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| 91 | ! REAL :: omegaREFir3d(ngrid,nlayer,naerkind) ! not sure of the point of these... |
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[222] | 92 | |
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| 93 | REAL,ALLOCATABLE,SAVE :: reffrad(:,:,:) ! aerosol effective radius (m) |
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| 94 | REAL,ALLOCATABLE,SAVE :: nueffrad(:,:,:) ! aerosol effective variance |
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[227] | 95 | !$OMP THREADPRIVATE(reffrad,nueffrad) |
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[222] | 96 | |
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| 97 | !----------------------------------------------------------------------- |
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| 98 | ! Declaration of the variables required by correlated-k subroutines |
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| 99 | ! Numbered from top to bottom unlike in the GCM! |
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| 100 | |
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| 101 | REAL*8 tmid(L_LEVELS),pmid(L_LEVELS) |
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| 102 | REAL*8 tlevrad(L_LEVELS),plevrad(L_LEVELS) |
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| 103 | |
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| 104 | ! Optical values for the optci/cv subroutines |
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| 105 | REAL*8 stel(L_NSPECTV),stel_fract(L_NSPECTV) |
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| 106 | REAL*8 dtaui(L_NLAYRAD,L_NSPECTI,L_NGAUSS) |
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| 107 | REAL*8 dtauv(L_NLAYRAD,L_NSPECTV,L_NGAUSS) |
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| 108 | REAL*8 cosbv(L_NLAYRAD,L_NSPECTV,L_NGAUSS) |
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| 109 | REAL*8 cosbi(L_NLAYRAD,L_NSPECTI,L_NGAUSS) |
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| 110 | REAL*8 wbari(L_NLAYRAD,L_NSPECTI,L_NGAUSS) |
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| 111 | REAL*8 wbarv(L_NLAYRAD,L_NSPECTV,L_NGAUSS) |
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| 112 | REAL*8 tauv(L_NLEVRAD,L_NSPECTV,L_NGAUSS) |
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| 113 | REAL*8 taucumv(L_LEVELS,L_NSPECTV,L_NGAUSS) |
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| 114 | REAL*8 taucumi(L_LEVELS,L_NSPECTI,L_NGAUSS) |
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| 115 | |
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| 116 | REAL*8 tauaero(L_LEVELS+1,naerkind) |
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| 117 | REAL*8 nfluxtopv,nfluxtopi,nfluxtop,fluxtopvdn |
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| 118 | real*8 nfluxoutv_nu(L_NSPECTV) ! outgoing band-resolved VI flux at TOA (W/m2) |
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| 119 | real*8 nfluxtopi_nu(L_NSPECTI) ! net band-resolved IR flux at TOA (W/m2) |
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| 120 | real*8 fluxupi_nu(L_NLAYRAD,L_NSPECTI) ! for 1D diagnostic |
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| 121 | REAL*8 fmneti(L_NLAYRAD),fmnetv(L_NLAYRAD) |
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| 122 | REAL*8 fluxupv(L_NLAYRAD),fluxupi(L_NLAYRAD) |
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| 123 | REAL*8 fluxdnv(L_NLAYRAD),fluxdni(L_NLAYRAD) |
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| 124 | REAL*8 albi,albv,acosz |
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| 125 | |
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| 126 | INTEGER ig,l,k,nw,iaer,irad |
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| 127 | INTEGER icount |
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| 128 | |
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| 129 | real szangle |
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| 130 | logical global1d |
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| 131 | save szangle,global1d |
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[227] | 132 | !$OMP THREADPRIVATE(szangle,global1d) |
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[222] | 133 | real*8 taugsurf(L_NSPECTV,L_NGAUSS-1) |
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| 134 | real*8 taugsurfi(L_NSPECTI,L_NGAUSS-1) |
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| 135 | |
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| 136 | real*8 qvar(L_LEVELS) ! mixing ratio of variable component (mol/mol) |
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| 137 | |
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| 138 | ! Local aerosol optical properties for each column on RADIATIVE grid |
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| 139 | real*8,save :: QXVAER(L_LEVELS+1,L_NSPECTV,naerkind) |
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| 140 | real*8,save :: QSVAER(L_LEVELS+1,L_NSPECTV,naerkind) |
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| 141 | real*8,save :: GVAER(L_LEVELS+1,L_NSPECTV,naerkind) |
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| 142 | real*8,save :: QXIAER(L_LEVELS+1,L_NSPECTI,naerkind) |
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| 143 | real*8,save :: QSIAER(L_LEVELS+1,L_NSPECTI,naerkind) |
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| 144 | real*8,save :: GIAER(L_LEVELS+1,L_NSPECTI,naerkind) |
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| 145 | |
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[227] | 146 | !REAL :: QREFvis3d(ngrid,nlayer,naerkind) |
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| 147 | !REAL :: QREFir3d(ngrid,nlayer,naerkind) |
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[222] | 148 | !save QREFvis3d, QREFir3d |
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| 149 | real, dimension(:,:,:), save, allocatable :: QREFvis3d |
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| 150 | real, dimension(:,:,:), save, allocatable :: QREFir3d |
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[227] | 151 | !$OMP THREADPRIVATE(QXVAER,QSVAER,GVAER,QXIAER,QSIAER,GIAER,QREFvis3d,QREFir3d) |
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[222] | 152 | |
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| 153 | |
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| 154 | ! Misc. |
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| 155 | logical nantest |
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| 156 | real*8 tempv(L_NSPECTV) |
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| 157 | real*8 tempi(L_NSPECTI) |
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| 158 | real*8 temp,temp1,temp2,pweight |
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| 159 | character(len=10) :: tmp1 |
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| 160 | character(len=10) :: tmp2 |
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| 161 | |
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| 162 | ! for fixed water vapour profiles |
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| 163 | integer i_var |
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| 164 | real RH |
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| 165 | real*8 pq_temp(nlayer) |
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| 166 | real ptemp, Ttemp, qsat |
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| 167 | |
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| 168 | ! real(KIND=r8) :: pq_temp(nlayer) ! better F90 way.. DOESNT PORT TO F77!!! |
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| 169 | |
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| 170 | !real ptime, pday |
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| 171 | logical OLRz |
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| 172 | real*8 NFLUXGNDV_nu(L_NSPECTV) |
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| 173 | |
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| 174 | |
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| 175 | ! for weird cloud test |
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| 176 | real pqtest(ngrid,nlayer,nq) |
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| 177 | |
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| 178 | real maxrad, minrad |
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| 179 | |
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| 180 | real,external :: CBRT |
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| 181 | |
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| 182 | ! included by RW for runaway greenhouse 1D study |
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[227] | 183 | real vtmp(nlayer) |
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[222] | 184 | REAL*8 muvarrad(L_LEVELS) |
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| 185 | |
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| 186 | !=============================================================== |
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| 187 | ! Initialization on first call |
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| 188 | |
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| 189 | qxvaer(:,:,:)=0.0 |
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| 190 | qsvaer(:,:,:)=0.0 |
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| 191 | gvaer(:,:,:) =0.0 |
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| 192 | |
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| 193 | qxiaer(:,:,:)=0.0 |
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| 194 | qsiaer(:,:,:)=0.0 |
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| 195 | giaer(:,:,:) =0.0 |
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| 196 | |
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| 197 | if(firstcall) then |
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| 198 | |
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| 199 | !!! ALLOCATED instances are necessary because of CLFvarying |
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| 200 | !!! strategy to call callcorrk twice in physiq... |
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[227] | 201 | IF(.not.ALLOCATED(QREFvis3d)) ALLOCATE(QREFvis3d(ngrid,nlayer,naerkind)) |
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| 202 | IF(.not.ALLOCATED(QREFir3d)) ALLOCATE(QREFir3d(ngrid,nlayer,naerkind)) |
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[222] | 203 | ! Effective radius and variance of the aerosols |
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| 204 | IF(.not.ALLOCATED(reffrad)) allocate(reffrad(ngrid,nlayer,naerkind)) |
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| 205 | IF(.not.ALLOCATED(nueffrad)) allocate(nueffrad(ngrid,nlayer,naerkind)) |
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| 206 | |
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[240] | 207 | !$OMP MASTER |
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[222] | 208 | call system('rm -f surf_vals_long.out') |
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[240] | 209 | !$OMP END MASTER |
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[222] | 210 | if(naerkind.gt.4)then |
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| 211 | print*,'Code not general enough to deal with naerkind > 4 yet.' |
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| 212 | call abort |
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| 213 | endif |
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[227] | 214 | call su_aer_radii(ngrid,nlayer,reffrad,nueffrad) |
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[222] | 215 | |
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| 216 | |
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| 217 | |
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| 218 | !-------------------------------------------------- |
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| 219 | ! set up correlated k |
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| 220 | print*, "callcorrk: Correlated-k data base folder:",trim(datadir) |
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[227] | 221 | call getin_p("corrkdir",corrkdir) |
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[222] | 222 | print*, "corrkdir = ",corrkdir |
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| 223 | write( tmp1, '(i3)' ) L_NSPECTI |
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| 224 | write( tmp2, '(i3)' ) L_NSPECTV |
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| 225 | banddir=trim(adjustl(tmp1))//'x'//trim(adjustl(tmp2)) |
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| 226 | banddir=trim(adjustl(corrkdir))//'/'//trim(adjustl(banddir)) |
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| 227 | |
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| 228 | call setspi ! basic infrared properties |
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| 229 | call setspv ! basic visible properties |
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| 230 | call sugas_corrk ! set up gaseous absorption properties |
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| 231 | call suaer_corrk ! set up aerosol optical properties |
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| 232 | |
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| 233 | |
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| 234 | if((igcm_h2o_vap.eq.0) .and. varactive)then |
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| 235 | print*,'varactive in callcorrk but no h2o_vap tracer.' |
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| 236 | stop |
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| 237 | endif |
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| 238 | |
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| 239 | OLR_nu(:,:) = 0. |
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| 240 | OSR_nu(:,:) = 0. |
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| 241 | |
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| 242 | if (ngrid.eq.1) then |
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| 243 | PRINT*, 'Simulate global averaged conditions ?' |
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| 244 | global1d = .false. ! default value |
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[227] | 245 | call getin_p("global1d",global1d) |
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[222] | 246 | write(*,*) "global1d = ",global1d |
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| 247 | ! Test of incompatibility: |
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| 248 | ! if global1d is true, there should not be any diurnal cycle |
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| 249 | if (global1d.and.diurnal) then |
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| 250 | print*,'if global1d is true, diurnal must be set to false' |
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| 251 | stop |
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| 252 | endif |
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| 253 | |
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| 254 | if (global1d) then |
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| 255 | PRINT *,'Solar Zenith angle (deg.) ?' |
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| 256 | PRINT *,'(assumed for averaged solar flux S/4)' |
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| 257 | szangle=60.0 ! default value |
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[227] | 258 | call getin_p("szangle",szangle) |
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[222] | 259 | write(*,*) "szangle = ",szangle |
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| 260 | endif |
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| 261 | endif |
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| 262 | |
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| 263 | end if ! of if (firstcall) |
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| 264 | |
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| 265 | !======================================================================= |
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| 266 | ! Initialization on every call |
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| 267 | |
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| 268 | !-------------------------------------------------- |
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| 269 | ! Effective radius and variance of the aerosols |
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| 270 | do iaer=1,naerkind |
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| 271 | |
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| 272 | if ((iaer.eq.iaero_co2).and.tracer.and.(igcm_co2_ice.gt.0)) then ! treat condensed co2 particles. |
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[227] | 273 | call co2_reffrad(ngrid,nlayer,nq,pq,reffrad(1,1,iaero_co2)) |
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| 274 | print*,'Max. CO2 ice particle size = ',maxval(reffrad(1:ngrid,1:nlayer,iaer))/1.e-6,' um' |
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| 275 | print*,'Min. CO2 ice particle size = ',minval(reffrad(1:ngrid,1:nlayer,iaer))/1.e-6,' um' |
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[222] | 276 | end if |
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| 277 | if ((iaer.eq.iaero_h2o).and.water) then ! treat condensed water particles. to be generalized for other aerosols |
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[227] | 278 | call h2o_reffrad(ngrid,nlayer,pq(1,1,igcm_h2o_ice),pt, & |
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[222] | 279 | reffrad(1,1,iaero_h2o),nueffrad(1,1,iaero_h2o)) |
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[227] | 280 | print*,'Max. H2O cloud particle size = ',maxval(reffrad(1:ngrid,1:nlayer,iaer))/1.e-6,' um' |
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| 281 | print*,'Min. H2O cloud particle size = ',minval(reffrad(1:ngrid,1:nlayer,iaer))/1.e-6,' um' |
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[222] | 282 | endif |
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| 283 | if(iaer.eq.iaero_dust)then |
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[227] | 284 | call dust_reffrad(ngrid,nlayer,reffrad(1,1,iaero_dust)) |
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[222] | 285 | print*,'Dust particle size = ',reffrad(1,1,iaer)/1.e-6,' um' |
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| 286 | endif |
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| 287 | if(iaer.eq.iaero_h2so4)then |
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[227] | 288 | call h2so4_reffrad(ngrid,nlayer,reffrad(1,1,iaero_h2so4)) |
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[222] | 289 | print*,'H2SO4 particle size =',reffrad(1,1,iaer)/1.e-6,' um' |
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| 290 | endif |
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| 291 | if(iaer.eq.iaero_back2lay)then |
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| 292 | call back2lay_reffrad(ngrid,reffrad(1,1,iaero_back2lay),nlayer,pplev) |
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| 293 | endif |
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| 294 | end do !iaer=1,naerkind |
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| 295 | |
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| 296 | |
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| 297 | ! how much light we get |
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| 298 | do nw=1,L_NSPECTV |
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| 299 | stel(nw)=stellarf(nw)/(dist_star**2) |
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| 300 | end do |
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| 301 | |
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| 302 | call aeroptproperties(ngrid,nlayer,reffrad,nueffrad, & |
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| 303 | QVISsQREF3d,omegaVIS3d,gVIS3d, & |
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| 304 | QIRsQREF3d,omegaIR3d,gIR3d, & |
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| 305 | QREFvis3d,QREFir3d) ! get 3D aerosol optical properties |
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| 306 | |
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| 307 | call aeropacity(ngrid,nlayer,nq,pplay,pplev,pq,aerosol, & |
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| 308 | reffrad,QREFvis3d,QREFir3d, & |
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| 309 | tau_col,cloudfrac,totcloudfrac,clearsky) ! get aerosol optical depths |
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| 310 | |
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| 311 | !----------------------------------------------------------------------- |
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| 312 | ! Starting Big Loop over every GCM column |
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| 313 | do ig=1,ngrid |
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| 314 | |
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| 315 | !======================================================================= |
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| 316 | ! Transformation of the GCM variables |
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| 317 | |
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| 318 | !----------------------------------------------------------------------- |
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| 319 | ! Aerosol optical properties Qext, Qscat and g |
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| 320 | ! The transformation in the vertical is the same as for temperature |
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| 321 | |
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| 322 | ! shortwave |
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| 323 | do iaer=1,naerkind |
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| 324 | DO nw=1,L_NSPECTV |
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[227] | 325 | do l=1,nlayer |
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[222] | 326 | |
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[227] | 327 | temp1=QVISsQREF3d(ig,nlayer+1-l,nw,iaer) & |
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| 328 | *QREFvis3d(ig,nlayer+1-l,iaer) |
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[222] | 329 | |
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[227] | 330 | temp2=QVISsQREF3d(ig,max(nlayer-l,1),nw,iaer) & |
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| 331 | *QREFvis3d(ig,max(nlayer-l,1),iaer) |
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[222] | 332 | |
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| 333 | qxvaer(2*l,nw,iaer) = temp1 |
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| 334 | qxvaer(2*l+1,nw,iaer)=(temp1+temp2)/2 |
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| 335 | |
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[227] | 336 | temp1=temp1*omegavis3d(ig,nlayer+1-l,nw,iaer) |
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| 337 | temp2=temp2*omegavis3d(ig,max(nlayer-l,1),nw,iaer) |
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[222] | 338 | |
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| 339 | qsvaer(2*l,nw,iaer) = temp1 |
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| 340 | qsvaer(2*l+1,nw,iaer)=(temp1+temp2)/2 |
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| 341 | |
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[227] | 342 | temp1=gvis3d(ig,nlayer+1-l,nw,iaer) |
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| 343 | temp2=gvis3d(ig,max(nlayer-l,1),nw,iaer) |
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[222] | 344 | |
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| 345 | gvaer(2*l,nw,iaer) = temp1 |
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| 346 | gvaer(2*l+1,nw,iaer)=(temp1+temp2)/2 |
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| 347 | |
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| 348 | end do |
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| 349 | |
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| 350 | qxvaer(1,nw,iaer)=qxvaer(2,nw,iaer) |
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[227] | 351 | qxvaer(2*nlayer+1,nw,iaer)=0. |
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[222] | 352 | |
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| 353 | qsvaer(1,nw,iaer)=qsvaer(2,nw,iaer) |
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[227] | 354 | qsvaer(2*nlayer+1,nw,iaer)=0. |
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[222] | 355 | |
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| 356 | gvaer(1,nw,iaer)=gvaer(2,nw,iaer) |
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[227] | 357 | gvaer(2*nlayer+1,nw,iaer)=0. |
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[222] | 358 | |
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| 359 | end do |
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| 360 | |
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| 361 | ! longwave |
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| 362 | DO nw=1,L_NSPECTI |
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[227] | 363 | do l=1,nlayer |
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[222] | 364 | |
---|
[227] | 365 | temp1=QIRsQREF3d(ig,nlayer+1-l,nw,iaer) & |
---|
| 366 | *QREFir3d(ig,nlayer+1-l,iaer) |
---|
[222] | 367 | |
---|
[227] | 368 | temp2=QIRsQREF3d(ig,max(nlayer-l,1),nw,iaer) & |
---|
| 369 | *QREFir3d(ig,max(nlayer-l,1),iaer) |
---|
[222] | 370 | |
---|
| 371 | qxiaer(2*l,nw,iaer) = temp1 |
---|
| 372 | qxiaer(2*l+1,nw,iaer)=(temp1+temp2)/2 |
---|
| 373 | |
---|
[227] | 374 | temp1=temp1*omegair3d(ig,nlayer+1-l,nw,iaer) |
---|
| 375 | temp2=temp2*omegair3d(ig,max(nlayer-l,1),nw,iaer) |
---|
[222] | 376 | |
---|
| 377 | qsiaer(2*l,nw,iaer) = temp1 |
---|
| 378 | qsiaer(2*l+1,nw,iaer)=(temp1+temp2)/2 |
---|
| 379 | |
---|
[227] | 380 | temp1=gir3d(ig,nlayer+1-l,nw,iaer) |
---|
| 381 | temp2=gir3d(ig,max(nlayer-l,1),nw,iaer) |
---|
[222] | 382 | |
---|
| 383 | giaer(2*l,nw,iaer) = temp1 |
---|
| 384 | giaer(2*l+1,nw,iaer)=(temp1+temp2)/2 |
---|
| 385 | |
---|
| 386 | end do |
---|
| 387 | |
---|
| 388 | qxiaer(1,nw,iaer)=qxiaer(2,nw,iaer) |
---|
[227] | 389 | qxiaer(2*nlayer+1,nw,iaer)=0. |
---|
[222] | 390 | |
---|
| 391 | qsiaer(1,nw,iaer)=qsiaer(2,nw,iaer) |
---|
[227] | 392 | qsiaer(2*nlayer+1,nw,iaer)=0. |
---|
[222] | 393 | |
---|
| 394 | giaer(1,nw,iaer)=giaer(2,nw,iaer) |
---|
[227] | 395 | giaer(2*nlayer+1,nw,iaer)=0. |
---|
[222] | 396 | |
---|
| 397 | end do |
---|
| 398 | end do |
---|
| 399 | |
---|
| 400 | ! test / correct for freaky s. s. albedo values |
---|
| 401 | do iaer=1,naerkind |
---|
| 402 | do k=1,L_LEVELS+1 |
---|
| 403 | |
---|
| 404 | do nw=1,L_NSPECTV |
---|
| 405 | if(qsvaer(k,nw,iaer).gt.1.05*qxvaer(k,nw,iaer))then |
---|
| 406 | print*,'Serious problems with qsvaer values' |
---|
| 407 | print*,'in callcorrk' |
---|
| 408 | call abort |
---|
| 409 | endif |
---|
| 410 | if(qsvaer(k,nw,iaer).gt.qxvaer(k,nw,iaer))then |
---|
| 411 | qsvaer(k,nw,iaer)=qxvaer(k,nw,iaer) |
---|
| 412 | endif |
---|
| 413 | end do |
---|
| 414 | |
---|
| 415 | do nw=1,L_NSPECTI |
---|
| 416 | if(qsiaer(k,nw,iaer).gt.1.05*qxiaer(k,nw,iaer))then |
---|
| 417 | print*,'Serious problems with qsiaer values' |
---|
| 418 | print*,'in callcorrk' |
---|
| 419 | call abort |
---|
| 420 | endif |
---|
| 421 | if(qsiaer(k,nw,iaer).gt.qxiaer(k,nw,iaer))then |
---|
| 422 | qsiaer(k,nw,iaer)=qxiaer(k,nw,iaer) |
---|
| 423 | endif |
---|
| 424 | end do |
---|
| 425 | |
---|
| 426 | end do |
---|
| 427 | end do |
---|
| 428 | |
---|
| 429 | !----------------------------------------------------------------------- |
---|
| 430 | ! Aerosol optical depths |
---|
| 431 | |
---|
| 432 | do iaer=1,naerkind ! a bug was here |
---|
| 433 | do k=0,nlayer-1 |
---|
| 434 | |
---|
| 435 | pweight=(pplay(ig,L_NLAYRAD-k)-pplev(ig,L_NLAYRAD-k+1))/ & |
---|
| 436 | (pplev(ig,L_NLAYRAD-k)-pplev(ig,L_NLAYRAD-k+1)) |
---|
| 437 | |
---|
| 438 | temp=aerosol(ig,L_NLAYRAD-k,iaer)/QREFvis3d(ig,L_NLAYRAD-k,iaer) |
---|
| 439 | |
---|
| 440 | tauaero(2*k+2,iaer)=max(temp*pweight,0.d0) |
---|
| 441 | tauaero(2*k+3,iaer)=max(temp-tauaero(2*k+2,iaer),0.d0) |
---|
| 442 | ! |
---|
| 443 | end do |
---|
| 444 | ! boundary conditions |
---|
| 445 | tauaero(1,iaer) = tauaero(2,iaer) |
---|
| 446 | tauaero(L_LEVELS+1,iaer) = tauaero(L_LEVELS,iaer) |
---|
| 447 | !tauaero(1,iaer) = 0. |
---|
| 448 | !tauaero(L_LEVELS+1,iaer) = 0. |
---|
| 449 | end do |
---|
| 450 | |
---|
| 451 | ! Albedo and emissivity |
---|
| 452 | albi=1-emis(ig) ! longwave |
---|
| 453 | albv=albedo(ig) ! shortwave |
---|
| 454 | |
---|
| 455 | if(nosurf.and.(albv.gt.0.0))then |
---|
| 456 | print*,'For open lower boundary in callcorrk must' |
---|
| 457 | print*,'have surface albedo set to zero!' |
---|
| 458 | call abort |
---|
| 459 | endif |
---|
| 460 | |
---|
| 461 | if ((ngrid.eq.1).and.(global1d)) then ! fixed zenith angle 'szangle' in 1D simulations w/ globally-averaged sunlight |
---|
| 462 | acosz = cos(pi*szangle/180.0) |
---|
| 463 | print*,'acosz=',acosz,', szangle=',szangle |
---|
| 464 | else |
---|
| 465 | acosz=mu0(ig) ! cosine of sun incident angle : 3D simulations or local 1D simulations using latitude |
---|
| 466 | endif |
---|
| 467 | |
---|
| 468 | !!! JL13: in the following, I changed some indices in the interpolations so that the model rsults are less dependent on the number of layers |
---|
| 469 | !!! the older verions are commented with the commetn !JL13index |
---|
| 470 | |
---|
| 471 | |
---|
| 472 | !----------------------------------------------------------------------- |
---|
| 473 | ! Water vapour (to be generalised for other gases eventually) |
---|
| 474 | |
---|
| 475 | if(varactive)then |
---|
| 476 | |
---|
| 477 | i_var=igcm_h2o_vap |
---|
| 478 | do l=1,nlayer |
---|
| 479 | qvar(2*l) = pq(ig,nlayer+1-l,i_var) |
---|
| 480 | qvar(2*l+1) = pq(ig,nlayer+1-l,i_var) |
---|
| 481 | !JL13index qvar(2*l+1) = (pq(ig,nlayer+1-l,i_var)+pq(ig,max(nlayer-l,1),i_var))/2 |
---|
| 482 | !JL13index ! Average approximation as for temperature... |
---|
| 483 | end do |
---|
| 484 | qvar(1)=qvar(2) |
---|
| 485 | |
---|
| 486 | elseif(varfixed)then |
---|
| 487 | |
---|
[227] | 488 | do l=1,nlayer ! here we will assign fixed water vapour profiles globally |
---|
[222] | 489 | RH = satval * ((pplay(ig,l)/pplev(ig,1) - 0.02) / 0.98) |
---|
| 490 | if(RH.lt.0.0) RH=0.0 |
---|
| 491 | |
---|
| 492 | ptemp=pplay(ig,l) |
---|
| 493 | Ttemp=pt(ig,l) |
---|
| 494 | call watersat(Ttemp,ptemp,qsat) |
---|
| 495 | |
---|
| 496 | !pq_temp(l) = qsat ! fully saturated everywhere |
---|
| 497 | pq_temp(l) = RH * qsat ! ~realistic profile (e.g. 80% saturation at ground) |
---|
| 498 | end do |
---|
| 499 | |
---|
| 500 | do l=1,nlayer |
---|
| 501 | qvar(2*l) = pq_temp(nlayer+1-l) |
---|
| 502 | qvar(2*l+1) = (pq_temp(nlayer+1-l)+pq_temp(max(nlayer-l,1)))/2 |
---|
| 503 | end do |
---|
| 504 | qvar(1)=qvar(2) |
---|
| 505 | |
---|
| 506 | ! Lowest layer of atmosphere |
---|
| 507 | RH = satval * (1 - 0.02) / 0.98 |
---|
| 508 | if(RH.lt.0.0) RH=0.0 |
---|
| 509 | |
---|
| 510 | ! ptemp = pplev(ig,1) |
---|
| 511 | ! Ttemp = tsurf(ig) |
---|
| 512 | ! call watersat(Ttemp,ptemp,qsat) |
---|
| 513 | |
---|
[227] | 514 | qvar(2*nlayer+1)= RH * qsat ! ~realistic profile (e.g. 80% saturation at ground) |
---|
[222] | 515 | |
---|
| 516 | else |
---|
| 517 | do k=1,L_LEVELS |
---|
| 518 | qvar(k) = 1.0D-7 |
---|
| 519 | end do |
---|
| 520 | end if |
---|
| 521 | |
---|
| 522 | if(.not.kastprof)then |
---|
| 523 | ! IMPORTANT: Now convert from kg/kg to mol/mol |
---|
| 524 | do k=1,L_LEVELS |
---|
| 525 | qvar(k) = qvar(k)/(epsi+qvar(k)*(1.-epsi)) |
---|
| 526 | end do |
---|
| 527 | end if |
---|
| 528 | |
---|
| 529 | !----------------------------------------------------------------------- |
---|
| 530 | ! kcm mode only |
---|
| 531 | if(kastprof)then |
---|
| 532 | |
---|
| 533 | ! initial values equivalent to mugaz |
---|
| 534 | DO l=1,nlayer |
---|
| 535 | muvarrad(2*l) = mugaz |
---|
| 536 | muvarrad(2*l+1) = mugaz |
---|
| 537 | END DO |
---|
| 538 | |
---|
| 539 | if(ngasmx.gt.1)then |
---|
| 540 | |
---|
| 541 | DO l=1,nlayer |
---|
| 542 | muvarrad(2*l) = muvar(ig,nlayer+2-l) |
---|
| 543 | muvarrad(2*l+1) = (muvar(ig,nlayer+2-l) + & |
---|
| 544 | muvar(ig,max(nlayer+1-l,1)))/2 |
---|
| 545 | END DO |
---|
| 546 | |
---|
| 547 | muvarrad(1) = muvarrad(2) |
---|
[227] | 548 | muvarrad(2*nlayer+1)=muvar(ig,1) |
---|
[222] | 549 | |
---|
| 550 | print*,'Recalculating qvar with VARIABLE epsi for kastprof' |
---|
| 551 | print*,'Assumes that the variable gas is H2O!!!' |
---|
| 552 | print*,'Assumes that there is only one tracer' |
---|
| 553 | !i_var=igcm_h2o_vap |
---|
| 554 | i_var=1 |
---|
| 555 | if(nq.gt.1)then |
---|
| 556 | print*,'Need 1 tracer only to run kcm1d.e' |
---|
| 557 | stop |
---|
| 558 | endif |
---|
| 559 | do l=1,nlayer |
---|
| 560 | vtmp(l)=pq(ig,l,i_var)/(epsi+pq(ig,l,i_var)*(1.-epsi)) |
---|
| 561 | !vtmp(l)=pq(ig,l,i_var)*muvar(ig,l+1)/mH2O !JL to be changed |
---|
| 562 | end do |
---|
| 563 | |
---|
| 564 | do l=1,nlayer |
---|
| 565 | qvar(2*l) = vtmp(nlayer+1-l) |
---|
| 566 | qvar(2*l+1) = vtmp(nlayer+1-l) |
---|
| 567 | ! qvar(2*l+1) = ( vtmp(nlayer+1-l) + vtmp(max(nlayer-l,1)) )/2 |
---|
| 568 | end do |
---|
| 569 | qvar(1)=qvar(2) |
---|
| 570 | |
---|
| 571 | print*,'Warning: reducing qvar in callcorrk.' |
---|
| 572 | print*,'Temperature profile no longer consistent ', & |
---|
| 573 | 'with saturated H2O. qsat=',satval |
---|
| 574 | do k=1,L_LEVELS |
---|
| 575 | qvar(k) = qvar(k)*satval |
---|
| 576 | end do |
---|
| 577 | |
---|
| 578 | endif |
---|
| 579 | else ! if kastprof |
---|
| 580 | DO l=1,nlayer |
---|
| 581 | muvarrad(2*l) = muvar(ig,nlayer+2-l) |
---|
| 582 | muvarrad(2*l+1) = (muvar(ig,nlayer+2-l)+muvar(ig,max(nlayer+1-l,1)))/2 |
---|
| 583 | END DO |
---|
| 584 | |
---|
| 585 | muvarrad(1) = muvarrad(2) |
---|
[227] | 586 | muvarrad(2*nlayer+1)=muvar(ig,1) |
---|
[222] | 587 | endif |
---|
| 588 | |
---|
| 589 | ! Keep values inside limits for which we have radiative transfer coefficients |
---|
| 590 | if(L_REFVAR.gt.1)then ! there was a bug here! |
---|
| 591 | do k=1,L_LEVELS |
---|
| 592 | if(qvar(k).lt.wrefvar(1))then |
---|
| 593 | qvar(k)=wrefvar(1)+1.0e-8 |
---|
| 594 | elseif(qvar(k).gt.wrefvar(L_REFVAR))then |
---|
| 595 | qvar(k)=wrefvar(L_REFVAR)-1.0e-8 |
---|
| 596 | endif |
---|
| 597 | end do |
---|
| 598 | endif |
---|
| 599 | |
---|
| 600 | !----------------------------------------------------------------------- |
---|
| 601 | ! Pressure and temperature |
---|
| 602 | |
---|
| 603 | DO l=1,nlayer |
---|
| 604 | plevrad(2*l) = pplay(ig,nlayer+1-l)/scalep |
---|
| 605 | plevrad(2*l+1) = pplev(ig,nlayer+1-l)/scalep |
---|
| 606 | tlevrad(2*l) = pt(ig,nlayer+1-l) |
---|
| 607 | tlevrad(2*l+1) = (pt(ig,nlayer+1-l)+pt(ig,max(nlayer-l,1)))/2 |
---|
| 608 | END DO |
---|
| 609 | |
---|
| 610 | plevrad(1) = 0. |
---|
| 611 | plevrad(2) = max(pgasmin,0.0001*plevrad(3)) |
---|
| 612 | |
---|
| 613 | tlevrad(1) = tlevrad(2) |
---|
[227] | 614 | tlevrad(2*nlayer+1)=tsurf(ig) |
---|
[222] | 615 | |
---|
| 616 | tmid(1) = tlevrad(2) |
---|
| 617 | tmid(2) = tlevrad(2) |
---|
| 618 | pmid(1) = plevrad(2) |
---|
| 619 | pmid(2) = plevrad(2) |
---|
| 620 | |
---|
| 621 | DO l=1,L_NLAYRAD-1 |
---|
| 622 | tmid(2*l+1) = tlevrad(2*l) |
---|
| 623 | tmid(2*l+2) = tlevrad(2*l) |
---|
| 624 | pmid(2*l+1) = plevrad(2*l) |
---|
| 625 | pmid(2*l+2) = plevrad(2*l) |
---|
| 626 | !JL13index tmid(2*l+1) = tlevrad(2*l+1) |
---|
| 627 | !JL13index tmid(2*l+2) = tlevrad(2*l+1) |
---|
| 628 | !JL13index pmid(2*l+1) = plevrad(2*l+1) |
---|
| 629 | !JL13index pmid(2*l+2) = plevrad(2*l+1) |
---|
| 630 | END DO |
---|
| 631 | pmid(L_LEVELS) = plevrad(L_LEVELS-1) |
---|
| 632 | tmid(L_LEVELS) = tlevrad(L_LEVELS-1) |
---|
| 633 | !JL13index pmid(L_LEVELS) = plevrad(L_LEVELS) |
---|
| 634 | !JL13index tmid(L_LEVELS) = tlevrad(L_LEVELS) |
---|
| 635 | |
---|
| 636 | ! test for out-of-bounds pressure |
---|
| 637 | if(plevrad(3).lt.pgasmin)then |
---|
| 638 | print*,'Minimum pressure is outside the radiative' |
---|
| 639 | print*,'transfer kmatrix bounds, exiting.' |
---|
| 640 | call abort |
---|
| 641 | elseif(plevrad(L_LEVELS).gt.pgasmax)then |
---|
| 642 | print*,'Maximum pressure is outside the radiative' |
---|
| 643 | print*,'transfer kmatrix bounds, exiting.' |
---|
| 644 | call abort |
---|
| 645 | endif |
---|
| 646 | |
---|
| 647 | ! test for out-of-bounds temperature |
---|
| 648 | do k=1,L_LEVELS |
---|
| 649 | if(tlevrad(k).lt.tgasmin)then |
---|
| 650 | print*,'Minimum temperature is outside the radiative' |
---|
| 651 | print*,'transfer kmatrix bounds' |
---|
| 652 | print*,"k=",k," tlevrad(k)=",tlevrad(k) |
---|
| 653 | print*,"tgasmin=",tgasmin |
---|
| 654 | if (strictboundcorrk) then |
---|
| 655 | call abort |
---|
| 656 | else |
---|
| 657 | print*,'***********************************************' |
---|
| 658 | print*,'we allow model to continue with tlevrad=tgasmin' |
---|
| 659 | print*,' ... we assume we know what you are doing ... ' |
---|
| 660 | print*,' ... but do not let this happen too often ... ' |
---|
| 661 | print*,'***********************************************' |
---|
| 662 | !tlevrad(k)=tgasmin |
---|
| 663 | endif |
---|
| 664 | elseif(tlevrad(k).gt.tgasmax)then |
---|
| 665 | print*,'Maximum temperature is outside the radiative' |
---|
| 666 | print*,'transfer kmatrix bounds, exiting.' |
---|
| 667 | print*,"k=",k," tlevrad(k)=",tlevrad(k) |
---|
| 668 | print*,"tgasmax=",tgasmax |
---|
| 669 | if (strictboundcorrk) then |
---|
| 670 | call abort |
---|
| 671 | else |
---|
| 672 | print*,'***********************************************' |
---|
| 673 | print*,'we allow model to continue with tlevrad=tgasmax' |
---|
| 674 | print*,' ... we assume we know what you are doing ... ' |
---|
| 675 | print*,' ... but do not let this happen too often ... ' |
---|
| 676 | print*,'***********************************************' |
---|
| 677 | !tlevrad(k)=tgasmax |
---|
| 678 | endif |
---|
| 679 | endif |
---|
| 680 | enddo |
---|
| 681 | do k=1,L_NLAYRAD+1 |
---|
| 682 | if(tmid(k).lt.tgasmin)then |
---|
| 683 | print*,'Minimum temperature is outside the radiative' |
---|
| 684 | print*,'transfer kmatrix bounds, exiting.' |
---|
| 685 | print*,"k=",k," tmid(k)=",tmid(k) |
---|
| 686 | print*,"tgasmin=",tgasmin |
---|
| 687 | if (strictboundcorrk) then |
---|
| 688 | call abort |
---|
| 689 | else |
---|
| 690 | print*,'***********************************************' |
---|
| 691 | print*,'we allow model to continue with tmid=tgasmin' |
---|
| 692 | print*,' ... we assume we know what you are doing ... ' |
---|
| 693 | print*,' ... but do not let this happen too often ... ' |
---|
| 694 | print*,'***********************************************' |
---|
| 695 | tmid(k)=tgasmin |
---|
| 696 | endif |
---|
| 697 | elseif(tmid(k).gt.tgasmax)then |
---|
| 698 | print*,'Maximum temperature is outside the radiative' |
---|
| 699 | print*,'transfer kmatrix bounds, exiting.' |
---|
| 700 | print*,"k=",k," tmid(k)=",tmid(k) |
---|
| 701 | print*,"tgasmax=",tgasmax |
---|
| 702 | if (strictboundcorrk) then |
---|
| 703 | call abort |
---|
| 704 | else |
---|
| 705 | print*,'***********************************************' |
---|
| 706 | print*,'we allow model to continue with tmid=tgasmin' |
---|
| 707 | print*,' ... we assume we know what you are doing ... ' |
---|
| 708 | print*,' ... but do not let this happen too often ... ' |
---|
| 709 | print*,'***********************************************' |
---|
| 710 | tmid(k)=tgasmax |
---|
| 711 | endif |
---|
| 712 | endif |
---|
| 713 | enddo |
---|
| 714 | |
---|
| 715 | !======================================================================= |
---|
| 716 | ! Calling the main radiative transfer subroutines |
---|
| 717 | |
---|
| 718 | |
---|
| 719 | Cmk= 0.01 * 1.0 / (glat(ig) * mugaz * 1.672621e-27) ! q_main=1.0 assumed |
---|
| 720 | glat_ig=glat(ig) |
---|
| 721 | |
---|
| 722 | !----------------------------------------------------------------------- |
---|
| 723 | ! Shortwave |
---|
| 724 | |
---|
| 725 | if(fract(ig) .ge. 1.0e-4) then ! only during daylight! |
---|
| 726 | if((ngrid.eq.1).and.(global1d))then |
---|
| 727 | do nw=1,L_NSPECTV |
---|
| 728 | stel_fract(nw)= stel(nw)* 0.25 / acosz |
---|
| 729 | ! globally averaged = divide by 4 |
---|
| 730 | ! but we correct for solar zenith angle |
---|
| 731 | end do |
---|
| 732 | else |
---|
| 733 | do nw=1,L_NSPECTV |
---|
| 734 | stel_fract(nw)= stel(nw) * fract(ig) |
---|
| 735 | end do |
---|
| 736 | endif |
---|
| 737 | call optcv(dtauv,tauv,taucumv,plevrad, & |
---|
| 738 | qxvaer,qsvaer,gvaer,wbarv,cosbv,tauray,tauaero, & |
---|
| 739 | tmid,pmid,taugsurf,qvar,muvarrad) |
---|
| 740 | |
---|
| 741 | call sfluxv(dtauv,tauv,taucumv,albv,dwnv,wbarv,cosbv, & |
---|
| 742 | acosz,stel_fract,gweight, & |
---|
| 743 | nfluxtopv,fluxtopvdn,nfluxoutv_nu,nfluxgndv_nu, & |
---|
| 744 | fmnetv,fluxupv,fluxdnv,fzerov,taugsurf) |
---|
| 745 | |
---|
| 746 | else ! during the night, fluxes = 0 |
---|
| 747 | nfluxtopv = 0.0d0 |
---|
| 748 | fluxtopvdn = 0.0d0 |
---|
| 749 | nfluxoutv_nu(:) = 0.0d0 |
---|
| 750 | nfluxgndv_nu(:) = 0.0d0 |
---|
| 751 | do l=1,L_NLAYRAD |
---|
| 752 | fmnetv(l)=0.0d0 |
---|
| 753 | fluxupv(l)=0.0d0 |
---|
| 754 | fluxdnv(l)=0.0d0 |
---|
| 755 | end do |
---|
| 756 | end if |
---|
| 757 | |
---|
| 758 | !----------------------------------------------------------------------- |
---|
| 759 | ! Longwave |
---|
| 760 | |
---|
| 761 | call optci(plevrad,tlevrad,dtaui,taucumi, & |
---|
| 762 | qxiaer,qsiaer,giaer,cosbi,wbari,tauaero,tmid,pmid, & |
---|
| 763 | taugsurfi,qvar,muvarrad) |
---|
| 764 | |
---|
| 765 | call sfluxi(plevrad,tlevrad,dtaui,taucumi,ubari,albi, & |
---|
| 766 | wnoi,dwni,cosbi,wbari,gweight,nfluxtopi,nfluxtopi_nu, & |
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| 767 | fmneti,fluxupi,fluxdni,fluxupi_nu,fzeroi,taugsurfi) |
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| 768 | |
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| 769 | !----------------------------------------------------------------------- |
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| 770 | ! Transformation of the correlated-k code outputs |
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| 771 | ! (into dtlw, dtsw, fluxsurf_lw, fluxsurf_sw, fluxtop_lw, fluxtop_sw) |
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| 772 | |
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| 773 | ! Flux incident at the top of the atmosphere |
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| 774 | fluxtop_dn(ig)=fluxtopvdn |
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| 775 | |
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| 776 | fluxtop_lw(ig) = real(nfluxtopi) |
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| 777 | fluxabs_sw(ig) = real(-nfluxtopv) |
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| 778 | fluxsurf_lw(ig) = real(fluxdni(L_NLAYRAD)) |
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| 779 | fluxsurf_sw(ig) = real(fluxdnv(L_NLAYRAD)) |
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| 780 | |
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| 781 | if(fluxtop_dn(ig).lt.0.0)then |
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| 782 | print*,'Achtung! fluxtop_dn has lost the plot!' |
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| 783 | print*,'fluxtop_dn=',fluxtop_dn(ig) |
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| 784 | print*,'acosz=',acosz |
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| 785 | print*,'aerosol=',aerosol(ig,:,:) |
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| 786 | print*,'temp= ',pt(ig,:) |
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| 787 | print*,'pplay= ',pplay(ig,:) |
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| 788 | call abort |
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| 789 | endif |
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| 790 | |
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| 791 | ! Spectral output, for exoplanet observational comparison |
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| 792 | if(specOLR)then |
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| 793 | do nw=1,L_NSPECTI |
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| 794 | OLR_nu(ig,nw)=nfluxtopi_nu(nw)/DWNI(nw) !JL Normalize to the bandwidth |
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| 795 | end do |
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| 796 | do nw=1,L_NSPECTV |
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| 797 | !GSR_nu(ig,nw)=nfluxgndv_nu(nw) |
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| 798 | OSR_nu(ig,nw)=nfluxoutv_nu(nw)/DWNV(nw) !JL Normalize to the bandwidth |
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| 799 | end do |
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| 800 | endif |
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| 801 | |
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| 802 | ! Finally, the heating rates |
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| 803 | |
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| 804 | DO l=2,L_NLAYRAD |
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| 805 | dtsw(ig,L_NLAYRAD+1-l)=(fmnetv(l)-fmnetv(l-1)) & |
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| 806 | *glat(ig)/(cpp*scalep*(plevrad(2*l+1)-plevrad(2*l-1))) |
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| 807 | dtlw(ig,L_NLAYRAD+1-l)=(fmneti(l)-fmneti(l-1)) & |
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| 808 | *glat(ig)/(cpp*scalep*(plevrad(2*l+1)-plevrad(2*l-1))) |
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| 809 | END DO |
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| 810 | |
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| 811 | ! These are values at top of atmosphere |
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| 812 | dtsw(ig,L_NLAYRAD)=(fmnetv(1)-nfluxtopv) & |
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| 813 | *glat(ig)/(cpp*scalep*(plevrad(3)-plevrad(1))) |
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| 814 | dtlw(ig,L_NLAYRAD)=(fmneti(1)-nfluxtopi) & |
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| 815 | *glat(ig)/(cpp*scalep*(plevrad(3)-plevrad(1))) |
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| 816 | |
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| 817 | ! --------------------------------------------------------------- |
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| 818 | end do ! end of big loop over every GCM column (ig = 1:ngrid) |
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| 819 | |
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| 820 | |
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| 821 | !----------------------------------------------------------------------- |
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| 822 | ! Additional diagnostics |
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| 823 | |
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| 824 | ! IR spectral output, for exoplanet observational comparison |
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| 825 | |
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| 826 | |
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| 827 | if(lastcall.and.(ngrid.eq.1))then ! could disable the 1D output, they are in the diagfi and diagspec... JL12 |
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| 828 | |
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| 829 | print*,'Saving scalar quantities in surf_vals.out...' |
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| 830 | print*,'psurf = ', pplev(1,1),' Pa' |
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| 831 | open(116,file='surf_vals.out') |
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| 832 | write(116,*) tsurf(1),pplev(1,1),fluxtop_dn(1), & |
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| 833 | real(-nfluxtopv),real(nfluxtopi) |
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| 834 | close(116) |
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| 835 | |
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| 836 | ! I am useful, please don`t remove me! |
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| 837 | ! if(specOLR)then |
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| 838 | ! open(117,file='OLRnu.out') |
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| 839 | ! do nw=1,L_NSPECTI |
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| 840 | ! write(117,*) OLR_nu(1,nw) |
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| 841 | ! enddo |
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| 842 | ! close(117) |
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| 843 | ! |
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| 844 | ! open(127,file='OSRnu.out') |
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| 845 | ! do nw=1,L_NSPECTV |
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| 846 | ! write(127,*) OSR_nu(1,nw) |
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| 847 | ! enddo |
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| 848 | ! close(127) |
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| 849 | ! endif |
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| 850 | |
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| 851 | ! OLR vs altitude: do it as a .txt file |
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| 852 | OLRz=.false. |
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| 853 | if(OLRz)then |
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| 854 | print*,'saving IR vertical flux for OLRz...' |
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| 855 | open(118,file='OLRz_plevs.out') |
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| 856 | open(119,file='OLRz.out') |
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| 857 | do l=1,L_NLAYRAD |
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| 858 | write(118,*) plevrad(2*l) |
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| 859 | do nw=1,L_NSPECTI |
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| 860 | write(119,*) fluxupi_nu(l,nw) |
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| 861 | enddo |
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| 862 | enddo |
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| 863 | close(118) |
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| 864 | close(119) |
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| 865 | endif |
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| 866 | |
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| 867 | endif |
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| 868 | |
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| 869 | ! see physiq.F for explanations about CLFvarying. This is temporary. |
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| 870 | if (lastcall .and. .not.CLFvarying) then |
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| 871 | IF( ALLOCATED( gasi ) ) DEALLOCATE( gasi ) |
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| 872 | IF( ALLOCATED( gasv ) ) DEALLOCATE( gasv ) |
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[227] | 873 | !$OMP BARRIER |
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| 874 | !$OMP MASTER |
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[222] | 875 | IF( ALLOCATED( pgasref ) ) DEALLOCATE( pgasref ) |
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| 876 | IF( ALLOCATED( tgasref ) ) DEALLOCATE( tgasref ) |
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| 877 | IF( ALLOCATED( wrefvar ) ) DEALLOCATE( wrefvar ) |
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| 878 | IF( ALLOCATED( pfgasref ) ) DEALLOCATE( pfgasref ) |
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[227] | 879 | !$OMP END MASTER |
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| 880 | !$OMP BARRIER |
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[222] | 881 | IF ( ALLOCATED(reffrad)) DEALLOCATE(reffrad) |
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| 882 | IF ( ALLOCATED(nueffrad)) DEALLOCATE(nueffrad) |
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| 883 | endif |
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| 884 | |
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| 885 | |
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| 886 | end subroutine callcorrk |
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