1 | module radlwsw_m |
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2 | |
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3 | IMPLICIT NONE |
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4 | |
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5 | contains |
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6 | |
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7 | SUBROUTINE radlwsw( & |
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8 | dist, rmu0, fract, & |
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9 | paprs, pplay,tsol,alb1, alb2, & |
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10 | t,q,wo,& |
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11 | cldfra, cldemi, cldtaupd,& |
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12 | ok_ade, ok_aie, flag_aerosol,& |
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13 | flag_aerosol_strat,& |
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14 | tau_aero, piz_aero, cg_aero,& |
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15 | cldtaupi, new_aod, & |
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16 | qsat, flwc, fiwc, & |
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17 | heat,heat0,cool,cool0,radsol,albpla,& |
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18 | topsw,toplw,solsw,sollw,& |
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19 | sollwdown,& |
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20 | topsw0,toplw0,solsw0,sollw0,& |
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21 | lwdn0, lwdn, lwup0, lwup,& |
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22 | swdn0, swdn, swup0, swup,& |
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23 | topswad_aero, solswad_aero,& |
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24 | topswai_aero, solswai_aero, & |
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25 | topswad0_aero, solswad0_aero,& |
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26 | topsw_aero, topsw0_aero,& |
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27 | solsw_aero, solsw0_aero, & |
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28 | topswcf_aero, solswcf_aero) |
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29 | |
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30 | |
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31 | |
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32 | USE DIMPHY |
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33 | USE assert_m, ONLY : assert |
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34 | USE infotrac, ONLY : type_trac |
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35 | #ifdef REPROBUS |
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36 | USE CHEM_REP, ONLY : solaireTIME, ok_SUNTIME, ndimozon |
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37 | #endif |
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38 | |
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39 | !====================================================================== |
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40 | ! Auteur(s): Z.X. Li (LMD/CNRS) date: 19960719 |
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41 | ! Objet: interface entre le modele et les rayonnements |
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42 | ! Arguments: |
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43 | ! dist-----input-R- distance astronomique terre-soleil |
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44 | ! rmu0-----input-R- cosinus de l'angle zenithal |
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45 | ! fract----input-R- duree d'ensoleillement normalisee |
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46 | ! co2_ppm--input-R- concentration du gaz carbonique (en ppm) |
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47 | ! paprs----input-R- pression a inter-couche (Pa) |
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48 | ! pplay----input-R- pression au milieu de couche (Pa) |
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49 | ! tsol-----input-R- temperature du sol (en K) |
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50 | ! alb1-----input-R- albedo du sol(entre 0 et 1) dans l'interval visible |
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51 | ! alb2-----input-R- albedo du sol(entre 0 et 1) dans l'interval proche infra-rouge |
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52 | ! t--------input-R- temperature (K) |
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53 | ! q--------input-R- vapeur d'eau (en kg/kg) |
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54 | ! cldfra---input-R- fraction nuageuse (entre 0 et 1) |
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55 | ! cldtaupd---input-R- epaisseur optique des nuages dans le visible (present-day value) |
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56 | ! cldemi---input-R- emissivite des nuages dans l'IR (entre 0 et 1) |
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57 | ! ok_ade---input-L- apply the Aerosol Direct Effect or not? |
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58 | ! ok_aie---input-L- apply the Aerosol Indirect Effect or not? |
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59 | ! flag_aerosol-input-I- aerosol flag from 0 to 6 |
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60 | ! flag_aerosol_strat-input-I- use stratospheric aerosols flag (T/F) |
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61 | ! tau_ae, piz_ae, cg_ae-input-R- aerosol optical properties (calculated in aeropt.F) |
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62 | ! cldtaupi-input-R- epaisseur optique des nuages dans le visible |
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63 | ! calculated for pre-industrial (pi) aerosol concentrations, i.e. with smaller |
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64 | ! droplet concentration, thus larger droplets, thus generally cdltaupi cldtaupd |
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65 | ! it is needed for the diagnostics of the aerosol indirect radiative forcing |
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66 | ! |
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67 | ! heat-----output-R- echauffement atmospherique (visible) (K/jour) |
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68 | ! cool-----output-R- refroidissement dans l'IR (K/jour) |
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69 | ! radsol---output-R- bilan radiatif net au sol (W/m**2) (+ vers le bas) |
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70 | ! albpla---output-R- albedo planetaire (entre 0 et 1) |
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71 | ! topsw----output-R- flux solaire net au sommet de l'atm. |
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72 | ! toplw----output-R- ray. IR montant au sommet de l'atmosphere |
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73 | ! solsw----output-R- flux solaire net a la surface |
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74 | ! sollw----output-R- ray. IR montant a la surface |
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75 | ! solswad---output-R- ray. solaire net absorbe a la surface (aerosol dir) |
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76 | ! topswad---output-R- ray. solaire absorbe au sommet de l'atm. (aerosol dir) |
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77 | ! solswai---output-R- ray. solaire net absorbe a la surface (aerosol ind) |
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78 | ! topswai---output-R- ray. solaire absorbe au sommet de l'atm. (aerosol ind) |
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79 | ! |
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80 | ! ATTENTION: swai and swad have to be interpreted in the following manner: |
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81 | ! --------- |
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82 | ! ok_ade=F & ok_aie=F -both are zero |
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83 | ! ok_ade=T & ok_aie=F -aerosol direct forcing is F_{AD} = topsw-topswad |
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84 | ! indirect is zero |
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85 | ! ok_ade=F & ok_aie=T -aerosol indirect forcing is F_{AI} = topsw-topswai |
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86 | ! direct is zero |
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87 | ! ok_ade=T & ok_aie=T -aerosol indirect forcing is F_{AI} = topsw-topswai |
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88 | ! aerosol direct forcing is F_{AD} = topswai-topswad |
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89 | ! |
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90 | |
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91 | !====================================================================== |
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92 | |
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93 | ! ==================================================================== |
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94 | ! Adapte au modele de chimie INCA par Celine Deandreis & Anne Cozic -- 2009 |
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95 | ! 1 = ZERO |
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96 | ! 2 = AER total |
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97 | ! 3 = NAT |
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98 | ! 4 = BC |
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99 | ! 5 = SO4 |
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100 | ! 6 = POM |
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101 | ! 7 = DUST |
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102 | ! 8 = SS |
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103 | ! 9 = NO3 |
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104 | ! |
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105 | ! ==================================================================== |
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106 | include "YOETHF.h" |
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107 | include "YOMCST.h" |
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108 | include "clesphys.h" |
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109 | include "iniprint.h" |
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110 | |
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111 | ! Input arguments |
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112 | REAL, INTENT(in) :: dist |
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113 | REAL, INTENT(in) :: rmu0(KLON), fract(KLON) |
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114 | REAL, INTENT(in) :: paprs(KLON,KLEV+1), pplay(KLON,KLEV) |
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115 | REAL, INTENT(in) :: alb1(KLON), alb2(KLON), tsol(KLON) |
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116 | REAL, INTENT(in) :: t(KLON,KLEV), q(KLON,KLEV) |
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117 | |
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118 | REAL, INTENT(in):: wo(:, :, :) ! dimension(KLON,KLEV, 1 or 2) |
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119 | ! column-density of ozone in a layer, in kilo-Dobsons |
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120 | ! "wo(:, :, 1)" is for the average day-night field, |
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121 | ! "wo(:, :, 2)" is for daylight time. |
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122 | |
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123 | LOGICAL, INTENT(in) :: ok_ade, ok_aie ! switches whether to use aerosol direct (indirect) effects or not |
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124 | INTEGER, INTENT(in) :: flag_aerosol ! takes value 0 (no aerosol) or 1 to 6 (aerosols) |
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125 | LOGICAL, INTENT(in) :: flag_aerosol_strat ! use stratospheric aerosols |
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126 | REAL, INTENT(in) :: cldfra(KLON,KLEV), cldemi(KLON,KLEV), cldtaupd(KLON,KLEV) |
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127 | REAL, INTENT(in) :: tau_aero(KLON,KLEV,9,2) ! aerosol optical properties (see aeropt.F) |
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128 | REAL, INTENT(in) :: piz_aero(KLON,KLEV,9,2) ! aerosol optical properties (see aeropt.F) |
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129 | REAL, INTENT(in) :: cg_aero(KLON,KLEV,9,2) ! aerosol optical properties (see aeropt.F) |
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130 | REAL, INTENT(in) :: cldtaupi(KLON,KLEV) ! cloud optical thickness for pre-industrial aerosol concentrations |
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131 | LOGICAL, INTENT(in) :: new_aod ! flag pour retrouver les resultats exacts de l'AR4 dans le cas ou l'on ne travaille qu'avec les sulfates |
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132 | REAL, INTENT(in) :: qsat(klon,klev) ! Variable pour iflag_rrtm=1 |
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133 | REAL, INTENT(in) :: flwc(klon,klev) ! Variable pour iflag_rrtm=1 |
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134 | REAL, INTENT(in) :: fiwc(klon,klev) ! Variable pour iflag_rrtm=1 |
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135 | |
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136 | ! Output arguments |
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137 | REAL, INTENT(out) :: heat(KLON,KLEV), cool(KLON,KLEV) |
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138 | REAL, INTENT(out) :: heat0(KLON,KLEV), cool0(KLON,KLEV) |
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139 | REAL, INTENT(out) :: radsol(KLON), topsw(KLON), toplw(KLON) |
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140 | REAL, INTENT(out) :: solsw(KLON), sollw(KLON), albpla(KLON) |
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141 | REAL, INTENT(out) :: topsw0(KLON), toplw0(KLON), solsw0(KLON), sollw0(KLON) |
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142 | REAL, INTENT(out) :: sollwdown(KLON) |
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143 | REAL, INTENT(out) :: swdn(KLON,kflev+1),swdn0(KLON,kflev+1) |
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144 | REAL, INTENT(out) :: swup(KLON,kflev+1),swup0(KLON,kflev+1) |
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145 | REAL, INTENT(out) :: lwdn(KLON,kflev+1),lwdn0(KLON,kflev+1) |
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146 | REAL, INTENT(out) :: lwup(KLON,kflev+1),lwup0(KLON,kflev+1) |
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147 | REAL, INTENT(out) :: topswad_aero(KLON), solswad_aero(KLON) ! output: aerosol direct forcing at TOA and surface |
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148 | REAL, INTENT(out) :: topswai_aero(KLON), solswai_aero(KLON) ! output: aerosol indirect forcing atTOA and surface |
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149 | REAL, DIMENSION(klon), INTENT(out) :: topswad0_aero |
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150 | REAL, DIMENSION(klon), INTENT(out) :: solswad0_aero |
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151 | REAL, DIMENSION(kdlon,9), INTENT(out) :: topsw_aero |
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152 | REAL, DIMENSION(kdlon,9), INTENT(out) :: topsw0_aero |
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153 | REAL, DIMENSION(kdlon,9), INTENT(out) :: solsw_aero |
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154 | REAL, DIMENSION(kdlon,9), INTENT(out) :: solsw0_aero |
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155 | REAL, DIMENSION(kdlon,3), INTENT(out) :: topswcf_aero |
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156 | REAL, DIMENSION(kdlon,3), INTENT(out) :: solswcf_aero |
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157 | |
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158 | ! Local variables |
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159 | REAL(KIND=8) ZFSUP(KDLON,KFLEV+1) |
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160 | REAL(KIND=8) ZFSDN(KDLON,KFLEV+1) |
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161 | REAL(KIND=8) ZFSUP0(KDLON,KFLEV+1) |
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162 | REAL(KIND=8) ZFSDN0(KDLON,KFLEV+1) |
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163 | REAL(KIND=8) ZFLUP(KDLON,KFLEV+1) |
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164 | REAL(KIND=8) ZFLDN(KDLON,KFLEV+1) |
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165 | REAL(KIND=8) ZFLUP0(KDLON,KFLEV+1) |
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166 | REAL(KIND=8) ZFLDN0(KDLON,KFLEV+1) |
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167 | REAL(KIND=8) zx_alpha1, zx_alpha2 |
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168 | INTEGER k, kk, i, j, iof, nb_gr |
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169 | REAL(KIND=8) PSCT |
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170 | REAL(KIND=8) PALBD(kdlon,2), PALBP(kdlon,2) |
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171 | REAL(KIND=8) PEMIS(kdlon), PDT0(kdlon), PVIEW(kdlon) |
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172 | REAL(KIND=8) PPSOL(kdlon), PDP(kdlon,KLEV) |
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173 | REAL(KIND=8) PTL(kdlon,kflev+1), PPMB(kdlon,kflev+1) |
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174 | REAL(KIND=8) PTAVE(kdlon,kflev) |
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175 | REAL(KIND=8) PWV(kdlon,kflev), PQS(kdlon,kflev) |
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176 | |
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177 | real(kind=8) POZON(kdlon, kflev, size(wo, 3)) ! mass fraction of ozone |
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178 | ! "POZON(:, :, 1)" is for the average day-night field, |
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179 | ! "POZON(:, :, 2)" is for daylight time. |
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180 | |
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181 | REAL(KIND=8) PAER(kdlon,kflev,5) |
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182 | REAL(KIND=8) PCLDLD(kdlon,kflev) |
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183 | REAL(KIND=8) PCLDLU(kdlon,kflev) |
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184 | REAL(KIND=8) PCLDSW(kdlon,kflev) |
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185 | REAL(KIND=8) PTAU(kdlon,2,kflev) |
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186 | REAL(KIND=8) POMEGA(kdlon,2,kflev) |
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187 | REAL(KIND=8) PCG(kdlon,2,kflev) |
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188 | REAL(KIND=8) zfract(kdlon), zrmu0(kdlon), zdist |
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189 | REAL(KIND=8) zheat(kdlon,kflev), zcool(kdlon,kflev) |
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190 | REAL(KIND=8) zheat0(kdlon,kflev), zcool0(kdlon,kflev) |
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191 | REAL(KIND=8) ztopsw(kdlon), ztoplw(kdlon) |
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192 | REAL(KIND=8) zsolsw(kdlon), zsollw(kdlon), zalbpla(kdlon) |
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193 | REAL(KIND=8) zsollwdown(kdlon) |
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194 | REAL(KIND=8) ztopsw0(kdlon), ztoplw0(kdlon) |
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195 | REAL(KIND=8) zsolsw0(kdlon), zsollw0(kdlon) |
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196 | REAL(KIND=8) zznormcp |
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197 | REAL(KIND=8) tauaero(kdlon,kflev,9,2) ! aer opt properties |
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198 | REAL(KIND=8) pizaero(kdlon,kflev,9,2) |
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199 | REAL(KIND=8) cgaero(kdlon,kflev,9,2) |
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200 | REAL(KIND=8) PTAUA(kdlon,2,kflev) ! present-day value of cloud opt thickness (PTAU is pre-industrial value), local use |
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201 | REAL(KIND=8) POMEGAA(kdlon,2,kflev) ! dito for single scatt albedo |
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202 | REAL(KIND=8) ztopswadaero(kdlon), zsolswadaero(kdlon) ! Aerosol direct forcing at TOAand surface |
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203 | REAL(KIND=8) ztopswad0aero(kdlon), zsolswad0aero(kdlon) ! Aerosol direct forcing at TOAand surface |
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204 | REAL(KIND=8) ztopswaiaero(kdlon), zsolswaiaero(kdlon) ! dito, indirect |
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205 | REAL(KIND=8) ztopsw_aero(kdlon,9), ztopsw0_aero(kdlon,9) |
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206 | REAL(KIND=8) zsolsw_aero(kdlon,9), zsolsw0_aero(kdlon,9) |
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207 | REAL(KIND=8) ztopswcf_aero(kdlon,3), zsolswcf_aero(kdlon,3) |
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208 | real, parameter:: dobson_u = 2.1415e-05 ! Dobson unit, in kg m-2 |
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209 | |
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210 | call assert(size(wo, 1) == klon, size(wo, 2) == klev, "radlwsw wo") |
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211 | ! initialisation |
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212 | tauaero(:,:,:,:)=0. |
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213 | pizaero(:,:,:,:)=0. |
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214 | cgaero(:,:,:,:)=0. |
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215 | |
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216 | ! |
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217 | !------------------------------------------- |
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218 | nb_gr = KLON / kdlon |
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219 | IF (nb_gr*kdlon .NE. KLON) THEN |
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220 | PRINT*, "kdlon mauvais:", KLON, kdlon, nb_gr |
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221 | CALL abort |
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222 | ENDIF |
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223 | IF (kflev .NE. KLEV) THEN |
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224 | PRINT*, "kflev differe de KLEV, kflev, KLEV" |
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225 | CALL abort |
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226 | ENDIF |
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227 | !------------------------------------------- |
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228 | DO k = 1, KLEV |
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229 | DO i = 1, KLON |
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230 | heat(i,k)=0. |
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231 | cool(i,k)=0. |
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232 | heat0(i,k)=0. |
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233 | cool0(i,k)=0. |
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234 | ENDDO |
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235 | ENDDO |
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236 | ! |
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237 | zdist = dist |
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238 | ! |
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239 | PSCT = solaire/zdist/zdist |
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240 | |
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241 | IF (type_trac == 'repr') THEN |
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242 | #ifdef REPROBUS |
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243 | if(ok_SUNTIME) PSCT = solaireTIME/zdist/zdist |
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244 | print*,'Constante solaire: ',PSCT*zdist*zdist |
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245 | #endif |
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246 | END IF |
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247 | |
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248 | DO j = 1, nb_gr |
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249 | iof = kdlon*(j-1) |
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250 | DO i = 1, kdlon |
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251 | zfract(i) = fract(iof+i) |
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252 | zrmu0(i) = rmu0(iof+i) |
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253 | PALBD(i,1) = alb1(iof+i) |
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254 | PALBD(i,2) = alb2(iof+i) |
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255 | PALBP(i,1) = alb1(iof+i) |
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256 | PALBP(i,2) = alb2(iof+i) |
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257 | PEMIS(i) = 1.0 |
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258 | PVIEW(i) = 1.66 |
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259 | PPSOL(i) = paprs(iof+i,1) |
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260 | zx_alpha1 = (paprs(iof+i,1)-pplay(iof+i,2))/(pplay(iof+i,1)-pplay(iof+i,2)) |
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261 | zx_alpha2 = 1.0 - zx_alpha1 |
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262 | PTL(i,1) = t(iof+i,1) * zx_alpha1 + t(iof+i,2) * zx_alpha2 |
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263 | PTL(i,KLEV+1) = t(iof+i,KLEV) |
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264 | PDT0(i) = tsol(iof+i) - PTL(i,1) |
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265 | ENDDO |
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266 | DO k = 2, kflev |
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267 | DO i = 1, kdlon |
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268 | PTL(i,k) = (t(iof+i,k)+t(iof+i,k-1))*0.5 |
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269 | ENDDO |
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270 | ENDDO |
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271 | DO k = 1, kflev |
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272 | DO i = 1, kdlon |
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273 | PDP(i,k) = paprs(iof+i,k)-paprs(iof+i,k+1) |
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274 | PTAVE(i,k) = t(iof+i,k) |
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275 | PWV(i,k) = MAX (q(iof+i,k), 1.0e-12) |
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276 | PQS(i,k) = PWV(i,k) |
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277 | POZON(i,k, :) = wo(iof+i, k, :) * RG * dobson_u * 1e3 & |
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278 | / (paprs(iof+i, k) - paprs(iof+i, k+1)) |
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279 | PCLDLD(i,k) = cldfra(iof+i,k)*cldemi(iof+i,k) |
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280 | PCLDLU(i,k) = cldfra(iof+i,k)*cldemi(iof+i,k) |
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281 | PCLDSW(i,k) = cldfra(iof+i,k) |
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282 | PTAU(i,1,k) = MAX(cldtaupi(iof+i,k), 1.0e-05)! 1e-12 serait instable |
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283 | PTAU(i,2,k) = MAX(cldtaupi(iof+i,k), 1.0e-05)! pour 32-bit machines |
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284 | POMEGA(i,1,k) = 0.9999 - 5.0e-04 * EXP(-0.5 * PTAU(i,1,k)) |
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285 | POMEGA(i,2,k) = 0.9988 - 2.5e-03 * EXP(-0.05 * PTAU(i,2,k)) |
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286 | PCG(i,1,k) = 0.865 |
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287 | PCG(i,2,k) = 0.910 |
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288 | !- |
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289 | ! Introduced for aerosol indirect forcings. |
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290 | ! The following values use the cloud optical thickness calculated from |
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291 | ! present-day aerosol concentrations whereas the quantities without the |
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292 | ! "A" at the end are for pre-industial (natural-only) aerosol concentrations |
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293 | ! |
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294 | PTAUA(i,1,k) = MAX(cldtaupd(iof+i,k), 1.0e-05)! 1e-12 serait instable |
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295 | PTAUA(i,2,k) = MAX(cldtaupd(iof+i,k), 1.0e-05)! pour 32-bit machines |
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296 | POMEGAA(i,1,k) = 0.9999 - 5.0e-04 * EXP(-0.5 * PTAUA(i,1,k)) |
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297 | POMEGAA(i,2,k) = 0.9988 - 2.5e-03 * EXP(-0.05 * PTAUA(i,2,k)) |
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298 | ENDDO |
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299 | ENDDO |
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300 | |
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301 | IF (type_trac == 'repr') THEN |
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302 | #ifdef REPROBUS |
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303 | ndimozon = size(wo, 3) |
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304 | CALL RAD_INTERACTIF(POZON,iof) |
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305 | #endif |
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306 | END IF |
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307 | |
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308 | ! |
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309 | DO k = 1, kflev+1 |
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310 | DO i = 1, kdlon |
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311 | PPMB(i,k) = paprs(iof+i,k)/100.0 |
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312 | ENDDO |
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313 | ENDDO |
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314 | ! |
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315 | DO kk = 1, 5 |
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316 | DO k = 1, kflev |
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317 | DO i = 1, kdlon |
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318 | PAER(i,k,kk) = 1.0E-15 |
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319 | ENDDO |
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320 | ENDDO |
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321 | ENDDO |
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322 | DO k = 1, kflev |
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323 | DO i = 1, kdlon |
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324 | tauaero(i,k,:,1)=tau_aero(iof+i,k,:,1) |
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325 | pizaero(i,k,:,1)=piz_aero(iof+i,k,:,1) |
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326 | cgaero(i,k,:,1) =cg_aero(iof+i,k,:,1) |
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327 | tauaero(i,k,:,2)=tau_aero(iof+i,k,:,2) |
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328 | pizaero(i,k,:,2)=piz_aero(iof+i,k,:,2) |
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329 | cgaero(i,k,:,2) =cg_aero(iof+i,k,:,2) |
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330 | ENDDO |
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331 | ENDDO |
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332 | |
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333 | ! |
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334 | !===== iflag_rrtm ================================================ |
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335 | ! |
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336 | print*,'iflag_rrtm = ', iflag_rrtm |
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337 | IF (iflag_rrtm == 0) THEN |
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338 | ! Old radiation scheme, used for AR4 runs |
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339 | ! average day-night ozone for longwave |
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340 | CALL LW_LMDAR4(& |
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341 | PPMB, PDP,& |
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342 | PPSOL,PDT0,PEMIS,& |
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343 | PTL, PTAVE, PWV, POZON(:, :, 1), PAER,& |
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344 | PCLDLD,PCLDLU,& |
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345 | PVIEW,& |
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346 | zcool, zcool0,& |
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347 | ztoplw,zsollw,ztoplw0,zsollw0,& |
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348 | zsollwdown,& |
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349 | ZFLUP, ZFLDN, ZFLUP0,ZFLDN0) |
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350 | |
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351 | ! daylight ozone, if we have it, for short wave |
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352 | IF (.NOT. new_aod) THEN |
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353 | ! use old version |
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354 | CALL SW_LMDAR4(PSCT, zrmu0, zfract,& |
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355 | PPMB, PDP, & |
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356 | PPSOL, PALBD, PALBP,& |
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357 | PTAVE, PWV, PQS, POZON(:, :, size(wo, 3)), PAER,& |
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358 | PCLDSW, PTAU, POMEGA, PCG,& |
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359 | zheat, zheat0,& |
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360 | zalbpla,ztopsw,zsolsw,ztopsw0,zsolsw0,& |
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361 | ZFSUP,ZFSDN,ZFSUP0,ZFSDN0,& |
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362 | tauaero(:,:,5,:), pizaero(:,:,5,:), cgaero(:,:,5,:),& |
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363 | PTAUA, POMEGAA,& |
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364 | ztopswadaero,zsolswadaero,& |
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365 | ztopswaiaero,zsolswaiaero,& |
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366 | ok_ade, ok_aie) |
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367 | |
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368 | ELSE ! new_aod=T |
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369 | CALL SW_AEROAR4(PSCT, zrmu0, zfract,& |
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370 | PPMB, PDP,& |
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371 | PPSOL, PALBD, PALBP,& |
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372 | PTAVE, PWV, PQS, POZON(:, :, size(wo, 3)), PAER,& |
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373 | PCLDSW, PTAU, POMEGA, PCG,& |
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374 | zheat, zheat0,& |
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375 | zalbpla,ztopsw,zsolsw,ztopsw0,zsolsw0,& |
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376 | ZFSUP,ZFSDN,ZFSUP0,ZFSDN0,& |
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377 | tauaero, pizaero, cgaero, & |
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378 | PTAUA, POMEGAA,& |
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379 | ztopswadaero,zsolswadaero,& |
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380 | ztopswad0aero,zsolswad0aero,& |
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381 | ztopswaiaero,zsolswaiaero, & |
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382 | ztopsw_aero,ztopsw0_aero,& |
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383 | zsolsw_aero,zsolsw0_aero,& |
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384 | ztopswcf_aero,zsolswcf_aero, & |
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385 | ok_ade, ok_aie, flag_aerosol,flag_aerosol_strat) |
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386 | ENDIF |
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387 | |
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388 | ELSE |
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389 | !===== iflag_rrtm=1, on passe dans SW via RECMWFL =============== |
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390 | WRITE(lunout,*) "Option iflag_rrtm=T ne fonctionne pas encore !!!" |
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391 | CALL abort_gcm('radlwsw','iflag_rrtm=T not valid',1) |
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392 | |
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393 | ENDIF ! iflag_rrtm |
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394 | !====================================================================== |
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395 | |
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396 | DO i = 1, kdlon |
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397 | radsol(iof+i) = zsolsw(i) + zsollw(i) |
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398 | topsw(iof+i) = ztopsw(i) |
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399 | toplw(iof+i) = ztoplw(i) |
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400 | solsw(iof+i) = zsolsw(i) |
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401 | sollw(iof+i) = zsollw(i) |
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402 | sollwdown(iof+i) = zsollwdown(i) |
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403 | DO k = 1, kflev+1 |
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404 | lwdn0 ( iof+i,k) = ZFLDN0 ( i,k) |
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405 | lwdn ( iof+i,k) = ZFLDN ( i,k) |
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406 | lwup0 ( iof+i,k) = ZFLUP0 ( i,k) |
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407 | lwup ( iof+i,k) = ZFLUP ( i,k) |
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408 | ENDDO |
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409 | topsw0(iof+i) = ztopsw0(i) |
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410 | toplw0(iof+i) = ztoplw0(i) |
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411 | solsw0(iof+i) = zsolsw0(i) |
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412 | sollw0(iof+i) = zsollw0(i) |
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413 | albpla(iof+i) = zalbpla(i) |
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414 | |
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415 | DO k = 1, kflev+1 |
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416 | swdn0 ( iof+i,k) = ZFSDN0 ( i,k) |
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417 | swdn ( iof+i,k) = ZFSDN ( i,k) |
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418 | swup0 ( iof+i,k) = ZFSUP0 ( i,k) |
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419 | swup ( iof+i,k) = ZFSUP ( i,k) |
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420 | ENDDO |
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421 | ENDDO |
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422 | !-transform the aerosol forcings, if they have |
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423 | ! to be calculated |
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424 | IF (ok_ade) THEN |
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425 | DO i = 1, kdlon |
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426 | topswad_aero(iof+i) = ztopswadaero(i) |
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427 | topswad0_aero(iof+i) = ztopswad0aero(i) |
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428 | solswad_aero(iof+i) = zsolswadaero(i) |
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429 | solswad0_aero(iof+i) = zsolswad0aero(i) |
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430 | ! MS the following lines seem to be wrong, why is iof on right hand side??? |
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431 | ! topsw_aero(iof+i,:) = ztopsw_aero(iof+i,:) |
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432 | ! topsw0_aero(iof+i,:) = ztopsw0_aero(iof+i,:) |
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433 | ! solsw_aero(iof+i,:) = zsolsw_aero(iof+i,:) |
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434 | ! solsw0_aero(iof+i,:) = zsolsw0_aero(iof+i,:) |
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435 | topsw_aero(iof+i,:) = ztopsw_aero(i,:) |
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436 | topsw0_aero(iof+i,:) = ztopsw0_aero(i,:) |
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437 | solsw_aero(iof+i,:) = zsolsw_aero(i,:) |
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438 | solsw0_aero(iof+i,:) = zsolsw0_aero(i,:) |
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439 | topswcf_aero(iof+i,:) = ztopswcf_aero(i,:) |
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440 | solswcf_aero(iof+i,:) = zsolswcf_aero(i,:) |
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441 | ENDDO |
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442 | ELSE |
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443 | DO i = 1, kdlon |
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444 | topswad_aero(iof+i) = 0.0 |
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445 | solswad_aero(iof+i) = 0.0 |
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446 | topswad0_aero(iof+i) = 0.0 |
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447 | solswad0_aero(iof+i) = 0.0 |
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448 | topsw_aero(iof+i,:) = 0. |
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449 | topsw0_aero(iof+i,:) =0. |
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450 | solsw_aero(iof+i,:) = 0. |
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451 | solsw0_aero(iof+i,:) = 0. |
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452 | ENDDO |
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453 | ENDIF |
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454 | IF (ok_aie) THEN |
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455 | DO i = 1, kdlon |
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456 | topswai_aero(iof+i) = ztopswaiaero(i) |
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457 | solswai_aero(iof+i) = zsolswaiaero(i) |
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458 | ENDDO |
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459 | ELSE |
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460 | DO i = 1, kdlon |
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461 | topswai_aero(iof+i) = 0.0 |
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462 | solswai_aero(iof+i) = 0.0 |
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463 | ENDDO |
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464 | ENDIF |
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465 | DO k = 1, kflev |
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466 | DO i = 1, kdlon |
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467 | ! scale factor to take into account the difference between |
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468 | ! dry air and watter vapour scpecifi! heat capacity |
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469 | zznormcp=1.0+RVTMP2*PWV(i,k) |
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470 | heat(iof+i,k) = zheat(i,k)/zznormcp |
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471 | cool(iof+i,k) = zcool(i,k)/zznormcp |
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472 | heat0(iof+i,k) = zheat0(i,k)/zznormcp |
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473 | cool0(iof+i,k) = zcool0(i,k)/zznormcp |
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474 | ENDDO |
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475 | ENDDO |
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476 | |
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477 | ENDDO ! j = 1, nb_gr |
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478 | |
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479 | END SUBROUTINE radlwsw |
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480 | |
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481 | end module radlwsw_m |
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